CN108287055B - Adjustable tidal wave experiment water tank device - Google Patents

Abstract

An adjustable tidal wave experiment water tank device belongs to the technical field of ocean engineering and hydrodynamic experiment research. The technical scheme is as follows: the method comprises the following steps: the water circulation device comprises a lifting water tank, a diversion trench, a leveling trench, a tidal wave marching trench, an overflow water tank and a matched water circulation device, wherein the lifting water tank is connected with the diversion trench, one end of the leveling trench is connected with the diversion trench, the other end of the leveling trench is connected with the tidal wave marching trench, the inlet of the matched water circulation device is connected with the overflow water tank, and the outlet of the matched water circulation device is connected with the lifting water tank and the leveling trench. The beneficial effects are that: the invention can adjust the simulated tidal wave tidal flow rising, tidal flow velocity, bay bottom gradient of the bay or estuary and bay mouth shrinkage rate of the bay or estuary, thereby accurately simulating the required tidal wave. The experimental water in the device can be recycled. The device has the advantages of scientific structure, reliable performance, convenient use, energy conservation and environmental protection.

Description

Adjustable tidal wave experiment water tank device

Technical Field

The invention relates to the technical field of ocean engineering and hydrodynamic experiment research, in particular to an adjustable tidal wave experiment water tank device.

Background

Tidal wave motion is the basic form of sea water motion, which is the phenomenon of water surface fluctuation due to the fluctuation of tides. Wide action range of tidal wave movement and long action time, and has important influence on production and life of people. Coastal areas with large tidal wave action are developed economically, have large population density and are influenced by the tidal waves for a long time, and particularly in gulf and estuary areas, the tidal waves have stronger movement. Deep research on tidal wave movement is of great significance to better develop and utilize tidal wave resources, more effectively prevent disasters caused by tidal waves and more quickly promote the development of national economy in coastal regions.

In a laboratory, the simulation of the action of the tidal wave and the structure by using a physical model test method is an effective means for studying the tidal wave. In the past tidal wave experiment, parameters such as the tidal current amount, the tidal current flow rate, the bottom slope of a bay, the shrinkage rate of a bay mouth and the like of a tidal wave can not be controlled by a water tank, real tidal wave motion is difficult to simulate, and great difficulty is brought to the tidal wave experiment. Therefore, the design of an adjustable tidal wave experiment water tank capable of controlling various experiment parameters is a problem which needs to be solved urgently at present.

Disclosure of Invention

The invention provides an adjustable tidal wave experiment water tank device, which can control the tidal flow volume, the tidal flow velocity, the bottom slope of a bay and the shrinkage rate of a bay mouth of a tidal wave and provide strips for accurately simulating tidal wave motion in a laboratory.

The technical scheme is as follows:

an adjustable tidal wave experiment water tank device, comprising: the water circulation device comprises a lifting type water tank, a diversion trench, a leveling trench, a tidal wave traveling trench, an overflow water tank and a matched water circulation device, wherein the lifting type water tank is connected with the diversion trench, one end of the leveling trench is connected with the diversion trench, the other end of the leveling trench is connected with the tidal wave traveling trench, the inlet of the matched water circulation device is connected with the overflow water tank, two outlets of the water circulation device are respectively connected with the lifting type water tank and the leveling trench, and the tidal wave traveling trench is connected with the overflow water tank.

Further, the over-and-under type water tank includes lift base, storage water tank, flow valve, goes out the sluice, the storage water tank is installed on the lift base, the flow valve is installed in the outside of storage water tank export, it installs the outside at the flow valve to go out the sluice.

Further, the guiding gutter includes concertina type rubber band I, basin I and axis of rotation I, the axis of rotation dress is in on the basin I, I bottom of concertina type rubber band with I connection of axis of rotation, concertina type rubber band I with the play sluice connection of over-and-under type water tank.

Further, the leveling groove comprises a telescopic rubber belt II, a telescopic rubber belt III, a water tank II, a rotating shaft III and a supporting base, wherein the water tank II is installed on the supporting base, the rotating shaft II and the rotating shaft III are respectively installed at two ends of the water tank II, the bottom of the telescopic rubber belt II is connected with the rotating shaft II, and the bottom of the telescopic rubber belt III is connected with the rotating shaft III; the telescopic rubber band II is connected with the diversion trench, and the telescopic rubber band III is connected with the tidal wave advancing trench.

Furthermore, the tidal wave advancing groove comprises a matched base, a lifting frame, a rectangular water groove, two side movable baffles, a horizontal adjusting rod and a water outlet valve, the rectangular water groove is arranged on the matched base, the lifting frame is positioned at one end of the matched base, and the height of the supporting rectangular water groove is adjusted in a lifting mode; the two side moving baffles are arranged on two opposite sides of the rectangular water tank in the length direction, and the horizontal adjusting rod is connected with the two side moving baffles and used for changing the included angle of the two side moving baffles; the water outlet valve is arranged on one side of the rectangular water tank.

Furthermore, the overflow water tank is arranged on the rear side of the tidal wave advancing groove and used for collecting the experimental water discharged after the experiment is finished and recycling the next experiment.

Furthermore, supporting water circle device includes water pump, three-way water valve and supporting pipeline, the water pump is installed supporting on the pipeline, the three-way water valve pass through supporting pipeline respectively with over-and-under type water tank, advection groove, overflow water tank are connected.

Furthermore, the lifting base comprises steel rectangular metal rods, cylindrical metal rods and manual hydraulic jacks, the steel rectangular metal rods are crossed in pairs, the cylindrical metal rods are movably connected, and the manual hydraulic jacks are arranged between the steel rectangular metal rods and used for adjusting the height of the lifting base.

Furthermore, the side walls of the diversion trench, the leveling trench and the tidal wave advancing trench are made of glass.

The invention has the beneficial effects that:

the adjustable tidal wave experiment water tank device can adjust the simulated tidal wave rising tidal flow, rising tidal flow rate, bay bottom gradient of a bay or a estuary and bay shrinkage rate of the bay or the estuary, so that the required tidal wave can be simulated accurately; the experimental water in the device can be recycled. The device has the advantages of scientific structure, reliable performance, convenient use, energy conservation and environmental protection.

1. In the invention, the rising tide flow rate of the tide wave can be freely adjusted through the height of the lifting water tank; the tidal current flow rate of the tidal wave can be changed under the condition that the tidal current flow is not changed, so that the real tidal wave condition is simulated.

2. The invention can control the water outlet flow of the lifting water tank by changing the size of the flow valve, and simulate the tidal wave flow which is in accordance with the actual state.

3. The invention can change the inclination angle of the tide wave advancing groove by adjusting the height of the tide wave advancing groove lifting frame; therefore, the bay or the estuary with different gradients can be simulated in the test, and the defects of the prior art are overcome.

4. In the invention, the shrinkage rate of the bay or the estuary can be simulated by changing the included angles of the movable baffles on the two sides of the traveling wave water tank; in actual operation, the adjustment can be easily performed only by rotating the horizontal adjusting rod, the operation is simple, and the device is efficient and practical.

5. The adjustable tidal wave experiment water tank is provided with a circulating water device; after one experiment is finished, water can be conveyed to the lifting water tank through the circulating water device for the next experiment; energy conservation and environmental protection, and avoids waste.

Drawings

FIG. 1 is a schematic perspective view of an adjustable tidal wave experiment water tank device according to the present invention;

FIG. 2 is a schematic side view of an adjustable tidal wave experiment water tank device according to the present invention;

FIG. 3 is a schematic perspective view of the structure of the lifting type water tank of the present invention, the structure number of which is 1;

fig. 4 is a schematic structural perspective view of a flow guide groove with the structural number 2 according to the present invention;

FIG. 5 is a schematic perspective view of the structure of a levelling trough of the present invention, structure number 3;

FIG. 6 is a schematic perspective view of the tidal wave travel trough of structure number 4 of the present invention;

FIG. 7 is a schematic structural plan view of a circulating water apparatus of the present invention, which is structurally numbered 6;

FIG. 8 is a perspective view of the lifting base of the present invention with the structure number 11;

FIG. 9 is a schematic sectional view of a horizontal adjustment rod of the present invention, structurally designated 45;

in the figure:

1. the device comprises a lifting water tank, 2. a diversion trench, 3. a leveling trench and 4. a tidal wave advancing trench; 5. overflow water tank, 6. matching water circulation device;

11. lifting base, water storage tank 12, flow valve 13, water outlet gate 14;

21. the telescopic rubber belts I and 22, the water tanks I and 23 and the rotating shaft I are arranged;

31. the telescopic rubber belts II and 32, the telescopic rubber belts III and 33, the water tanks II and 34, the rotating shafts II and 35, the rotating shafts III and 36 and the supporting base;

41. the water tank comprises a matched base, a lifting frame 42, a rectangular water tank 43, movable baffles on two sides 44, a horizontal adjusting rod 45 and a water outlet valve 46;

61. water pump, 62 three-way water valve, 63-66 pipeline.

Detailed Description

Example 1

The present invention will be described in further detail with reference to the following examples, which are carried out on the premise of the technical solution of the present invention. The embodiment gives a detailed implementation manner and a specific operation process, so that the purposes, technical schemes and advantages of the embodiment of the invention are clearer. The examples given are not to be construed as limiting the scope of the invention and therefore insubstantial modifications and adaptations made in accordance with the teachings and concepts of the invention are intended to be covered thereby.

As shown in fig. 1 and 2, the adjustable tidal wave experiment water tank experimental device comprises a lifting type water tank 1, a diversion water tank 2, a advection water tank 3, a tidal wave advancing tank 4, an overflow water tank 5 and a matched water circulation device 6.

The lifting water tank shown in fig. 3 comprises a lifting base 11, a water storage tank 12, a flow valve 13 and a water outlet gate 14. The lifting base shown in fig. 8 consists of 6 steel rectangular metal rods and 4 cylindrical metal rods and a manual hydraulic jack. The height of the lifting water tank is adjusted by adjusting the hydraulic jack. The water tank 12 is a steel square tank, has no cover on the upper part, and is provided with a square opening door at the lower end of one side of the water tank for draining water and producing tide waves. The flow valve 13 is positioned on the outer side of the port door and consists of valve grooves and valves on two sides of the port door, and the size of the water outlet flow is controlled by adjusting the valves up and down. The outlet sluice 14 is mounted outside the flow valve and when the outlet sluice is opened the water in the tank leaks out forming a tidal wave.

The diversion water tank shown in fig. 4 comprises a telescopic rubber belt I21, a water tank I22 and a rotating shaft I23. The telescopic rubber belt I21 is fan-shaped and made of rubber, and is mainly used for connecting a water tank and preventing water leakage. The upper side of the water tank I22 is opened, and the side wall is made of glass, so that the experimental phenomenon can be conveniently observed.

The advection water tank shown in fig. 5 comprises a telescopic rubber belt II 31, a telescopic rubber belt III 32, a water tank II 33, a rotating shaft II 34, a rotating shaft III 35 and a supporting base 36. The telescopic rubber belts II 31 and 32 are the same as the guide water tank 21, and the rotating shafts II 34 and III 35 are the same as the guide water tank 23. The side wall of the water tank II 33 is made of glass, and the upper side of the water tank II is open. The support base 36 is composed of angle steel.

The tide wave traveling groove shown in fig. 6 is composed of a matched base 41, a lifting frame 42, a rectangular water groove 43, two side movable baffles 44, a horizontal adjusting rod 45 and a water outlet valve 46. The mating base 41 is composed of angle steel, and the upper side is kept horizontal. The lifting frame 42 is arranged at the tail part of the matched base and consists of a rectangular metal rod, and the price lifting frame is provided with a manual hydraulic jack which can freely adjust the height of the lifting frame. The upper side of the rectangular water tank 43 is open, the side wall is made of glass, and the tail of the water tank is provided with a groove for placing the lifting frame. When the crane is completely put down, the advancing water tank is in a horizontal state. The front ends of the movable baffles 44 at both sides and the vertical wall at the front end of the rectangular water tank are connected by a rotating shaft. The horizontal adjustment bar 45 shown in fig. 9 is connected to both side walls of the rectangular sink and the movable barriers. The horizontal adjusting rod is provided with threads, when the adjusting rod rotates, the tails of the movable baffles on the two sides move towards opposite directions along with the adjusting rod, and the included angle of the two movable baffles is changed accordingly. An outlet valve 46 is mounted at the end of the rectangular tank and when the valve is opened, the water in the tank flows out into the overflow tank 5.

The overflow water tank 5 is a steel square tank, the upper side of the tank is open, and the side wall of the tank is connected with the pipeline 63.

The water circulation device shown in fig. 7 is connected by a water pump 61, a three-way water valve 62 and pipes 63, 64, 65 and 66. When the pump is turned on, water flows from the conduit 63 to the conduit 64. A three-way water valve can control the flow of water in the conduit 64 to either 65 or 66. Wherein the water in the 65 flows into the elevation type water tank 1 and the water in the 66 flows to the advection water tank 3.

The specific working steps of the adjustable tidal wave experiment water tank device provided by the embodiment are as follows:

the tidal wave trough crane 42 is adjusted to adjust the tidal wave trough to a desired angle according to the slope of the bay or estuary. When the simulated bay is a flat bay, the crane need not be raised, and the tidal wave travel trough is now flat. The horizontal adjusting rod 45 of the tide wave advancing groove is rotated, so that the included angle of the two movable baffles 44 is adjusted to be equal to the shrinkage rate of the gulf mouth.

The valve 62 is adjusted to the state of water flowing through the pipe 66, the water pump 61 is started, and the water in the water tank is added to the static water level required by the experiment. And measuring the height of the water level, namely reading the height of the liquid level below the water surface when the water surface is calm. Then the valve 63 is adjusted to be in a water-passing state through the pipe 65, the water pump 62 is started, and the water in the lifting water tank is added to the liquid level required by the experiment.

According to the tidal wave flow rate required by the experiment, the lifting base 11 is adjusted through a hydraulic jack, so that the height of the lifting water tank 12 is controlled. And adjusting the opening size of the flow valve 13 according to the tidal wave flow required by the experiment, thereby controlling the rising flow volume of the tidal wave. And after the adjustment is finished, waiting for the liquid level in the water tank to be static. Then the water outlet sluice 14 is opened, the water in the water tank is discharged, flows into the leveling channel 3 through the diversion channel 2, then forms the tide wave required by the experiment in the tide wave advancing channel 4, and records the experiment phenomenon.

After the experiment is finished, the tidal wave lifting frame is lowered to the lowest position, a water outlet valve of the advancing groove is opened, all water in the water tank is discharged to the overflow water tank, and then the water outlet valve is closed. And closing a water outlet gate of the lifting water tank and closing the flow valve.

Example 2

An adjustable tidal wave experiment water tank device, comprising: the tidal wave water circulation device comprises a lifting water tank 1, a diversion trench 2, a leveling trench 3, a tidal wave traveling trench 4, an overflow water tank 5 and a matched water circulation device 6, wherein the lifting water tank 1 is connected with the diversion trench 2, one end of the leveling trench 3 is connected with the diversion trench 2, the other end of the leveling trench 3 is connected with the tidal wave traveling trench 4, the inlet of the matched water circulation device 6 is connected with the overflow water tank 5, and the outlet of the matched water circulation device is connected with the lifting water tank 1 and the leveling trench 3.

Over-and-under type water tank 1 includes lift base 11, storage water tank 12, flow valve 13, goes out floodgate 14, storage water tank 12 is installed on lift base 11, flow valve 13 is installed in the outside of storage water tank 12 export, it installs in flow valve 13's the outside to go out floodgate 14. Wherein the lifting base 11 is used for adjusting the height of the water storage tank 12. The device changes the potential energy of the water body in the water storage tank 12 by controlling the height of the water storage tank 12, thereby controlling the tidal current velocity of the tidal wave. The water storage tank 12 is a square iron box with an open upper end and a square water outlet door arranged below one side facing the water tank. The water storage tank 12 is used to store experimental water that generates tidal waves. The flow valve 13 is positioned outside the mouth of the water storage tank 12, and the outlet water flow can be controlled by adjusting the size of the valve. The water outlet gate 14 is located outside the flow valve 13, and when the gate is opened, water of the water storage tank 12 flows out to form a tidal wave in the tidal wave travel tank 4 through the diversion trench 2 and the horizontal trench 3.

The diversion trench 2 comprises a telescopic rubber belt I21, a water tank I22 and a rotating shaft I23, wherein the rotating shaft 23 is arranged on the water tank I22, the bottom of the telescopic rubber belt I21 is connected with the rotating shaft I23, and the telescopic rubber belt I21 is connected with the lifting water tank 1. The inclination angle of the diversion trench 2 automatically changes along with the change of the height of the water tank.

The leveling tank 3 comprises a telescopic rubber belt II 31, a telescopic rubber belt III 32, a water tank II 33, a rotating shaft II 34, a rotating shaft III 35 and a supporting base 36, wherein the water tank II 33 is installed on the supporting base 36, the rotating shaft II 34 and the rotating shaft III 35 are respectively installed at two ends of the water tank II 33, the bottom of the telescopic rubber belt II 31 is connected with the rotating shaft II 34, and the bottom of the telescopic rubber belt III 32 is connected with the rotating shaft III 35; the telescopic rubber band II 31 is connected with the diversion trench 2, and the telescopic rubber band III 32 is connected with the tidal wave advancing trench 4. The leveling channel 3 is used for adjusting the travel angle of the tide wave to be horizontal and enabling the tide to come and go evenly and stably.

The tidal wave advancing groove 4 comprises a matched base 41, a lifting frame 42, a rectangular water groove 43, two side movable baffle plates 44, a horizontal adjusting rod 45 and a water outlet valve 46, wherein the rectangular water groove 43 is arranged on the matched base 41, and the lifting frame 42 is positioned at one end of the matched base 41 and is used for supporting the rectangular water groove 43 to adjust the height; the two side moving baffles 44 are arranged on two sides of the rectangular water tank 43, and the horizontal adjusting rod 45 is connected with the two side moving baffles 44 and used for changing the included angle of the two side moving baffles 44; the outlet valve 46 is installed at one side of the rectangular water tank 43. The elevation angle of the tidal wave travel trough 4 is controlled by adjusting the height of the elevation bracket 42. During the experiment, the inclination angle of the tidal wave traveling groove 4 corresponds to the simulated slope angle of the bay and the estuary. The tail of the water tank is provided with a groove, the upper end of the lifting frame 42 is positioned in the groove, and when the lifting frame 42 is completely put down, the tide wave advancing tank 3 is in a horizontal state. A vertical movable baffle is installed on each of the left and right inner sides of the rectangular water tank 43. The front end of the baffle plate is connected to the front vertical wall of the rectangular water tank 43 by a rotating shaft. The rear ends of the two baffles are connected with the side wall of the rectangular water tank 43 through a horizontal adjusting rod 45. The horizontal adjusting rod 45 is engraved with threads, and the distance between the tails of the two side moving baffles 44 can be changed by rotating the horizontal adjusting rod 45, so that the included angle of the two side moving baffles 44 can be adjusted. The angle of the two side moving flaps 44 is determined according to the gulf contraction rate of the simulated bay or river. The outlet valve 46 is installed at a rear side position of the tidal wave travel tank 4, and is mainly used to discharge the test water in the rectangular water tank 43 into the overflow tank 5 after the test.

The overflow water tank 5 is arranged at the rear side of the tidal wave advancing groove 4 and used for collecting the experimental water discharged after the experiment is finished and recycling the next experiment.

The matched water circulation device 6 comprises a water pump 61, a three-way water valve 62 and a matched pipeline, wherein the water pump 61 is installed on the matched pipeline, and the three-way water valve 62 is respectively connected with the lifting water tank 1, the leveling tank 3 and the overflow water tank 5 through the matched pipeline. The water pump 61 may pump out the water in the overflow tank 5. The three-way water valve 62 can control the experimental water in the overflow water tank to flow into the lifting water tank 1 or the leveling tank 3.

The lifting base 11 comprises steel rectangular metal rods, cylindrical metal rods and manual hydraulic jacks, the steel rectangular metal rods are crossed in pairs, the cylindrical metal rods are movably connected, and the manual hydraulic jacks are arranged between the steel rectangular metal rods and used for the height of the lifting base 11.

The side walls of the diversion trench 2, the leveling trench 3 and the tidal wave advancing trench 4 are made of glass.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (8)

1. The utility model provides a tidal wave experiment basin device with adjustable which characterized in that includes: the device comprises a lifting water tank (1), a diversion trench (2), a leveling trench (3), a tidal wave traveling trench (4), an overflow water tank (5) and a matched water circulation device (6), wherein the lifting water tank (1) is connected with the diversion trench (2), one end of the leveling trench (3) is connected with the diversion trench (2), the other end of the leveling trench (3) is connected with the tidal wave traveling trench (4), an inlet of the matched water circulation device (6) is connected with the overflow water tank (5), two outlets of the water circulation device (6) are respectively connected with the lifting water tank (1) and the leveling trench (3), and the tidal wave traveling trench (4) is connected with the overflow water tank (5); the diversion trench (2) includes I (21) of concertina type rubber band, basin I (22) and axis of rotation I (23), axis of rotation (23) dress is in on the basin I (22), I (21) bottom of concertina type rubber band with I (23) of axis of rotation are connected, I (21) of concertina type rubber band with go out water brake (14) of over-and-under type water tank (1) are connected.

2. The adjustable tidal wave experiment water tank device according to claim 1, wherein: over-and-under type water tank (1) is including lift base (11), storage water tank (12), flow valve (13), play floodgate (14), install storage water tank (12) on lift base (11), the outside at storage water tank (12) export is installed in flow valve (13), the outside at flow valve (13) is installed in play floodgate (14).

3. The adjustable tidal wave experiment water tank device according to claim 1, wherein: the leveling tank (3) comprises a telescopic rubber belt II (31), a telescopic rubber belt III (32), a water tank II (33), a rotating shaft II (34), a rotating shaft III (35) and a supporting base (36), the water tank II (33) is installed on the supporting base (36), the rotating shaft II (34) and the rotating shaft III (35) are respectively installed at two ends of the water tank II (33), the bottom of the telescopic rubber belt II (31) is connected with the rotating shaft II (34), and the bottom of the telescopic rubber belt III (32) is connected with the rotating shaft III (35); the telescopic rubber band II (31) is connected with the diversion trench (2), and the telescopic rubber band III (32) is connected with the tidal wave advancing trench (4).

4. The adjustable tidal wave experiment water tank device according to claim 1, wherein: the tidal wave advancing groove (4) comprises a matched base (41), a lifting frame (42), a rectangular water groove (43), two side movable baffles (44), a horizontal adjusting rod (45) and a water outlet valve (46), wherein the rectangular water groove (43) is arranged on the matched base (41), the lifting frame (42) is positioned at one end of the matched base (41), and the height of the supporting rectangular water groove (43) is adjusted in a lifting mode; the two side movable baffles (44) are arranged on two opposite sides of the rectangular water tank (43) in the length direction, and the horizontal adjusting rod (45) is connected with the two side movable baffles (44) and used for changing the included angle of the two side movable baffles (44); the water outlet valve (46) is arranged on one side of the rectangular water tank (43) connected with the overflow water tank.

5. The adjustable tidal wave experiment water tank device according to claim 1, wherein: the overflow water tank (5) is arranged on the rear side of the tide wave advancing groove (4) and used for collecting the experimental water discharged after the experiment is finished and recycling the next experiment.

6. The adjustable tidal wave experiment water tank device according to claim 1, wherein: supporting water circle device (6) include water pump (61), three-way water valve (62) and supporting pipeline, water pump (61) are installed on the supporting pipeline, three-way water valve (62) through supporting pipeline respectively with over-and-under type water tank (1), advection groove (3), overflow tank (5) are connected.

7. The adjustable tidal wave experiment water tank device according to claim 2, wherein: the lifting base (11) comprises steel rectangular metal rod frames, cylindrical metal rods and manual hydraulic jacks, the steel rectangular metal rod frames are crossed in pairs and movably connected through the cylindrical metal rods, and the manual hydraulic jacks are arranged between the steel rectangular metal rod frames and used for adjusting the height of the lifting base (11).

8. The adjustable tidal wave experiment sink device according to any one of claims 1 to 7, wherein: the side walls of the diversion trench (2), the leveling trench (3) and the tidal wave advancing trench (4) are made of glass.

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