CN111337223A - Harbor basin simulation device and test method thereof - Google Patents

Abstract

The invention discloses a harbor basin simulation device and a test method thereof, the harbor basin simulation device comprises a harbor basin, a water basin is arranged on one side edge of the harbor basin, a control panel is arranged on one side edge of the harbor basin far away from the water basin, a first fan is arranged at the top of the harbor basin, a second fan is arranged on one side edge of the harbor basin far away from the first fan, a third fan is arranged on one side edge of the harbor basin far away from the control panel and perpendicular to the first fan and the second fan, fan housings are arranged on one side edges of the first fan, the second fan and the third fan close to the harbor basin, a plurality of sensors are uniformly arranged in the harbor basin, water level scales are symmetrically arranged in the harbor basin and between the sensors, a wave generator is arranged in the harbor basin and on one side far away from the control panel, a transverse plate is arranged on, and the transverse plate is uniformly provided with a plurality of cameras.

Description

Harbor basin simulation device and test method thereof

Technical Field

The invention relates to the technical field of harbor ponds, in particular to a harbor pond simulation device and a test method thereof.

Background

The harbor basin has enough area and water depth, and requires small wind wave and stable water flow, and is formed by natural topography, artificial buildings and artificial excavation, and is called digging harbor basin; during construction of the harbor pool, the specific situation of the harbor pool needs to be simulated, so that the harbor pool can be better used after the construction is finished; the existing method for simulating the harbor basin cannot test the wind wave parameters and the water flow parameters under different conditions, so that the quality of the harbor basin is influenced, and the use requirements of people cannot be better met.

In summary, how to better perform a simulation test of a harbor basin is a technical problem which needs to be solved urgently at present.

Disclosure of Invention

The technical task of the invention is to provide a harbor basin simulation device and a test method thereof to solve the problem of how to better perform a simulation test of a harbor basin.

The technical scheme of the invention is realized as follows:

a harbor pool simulation device comprises a harbor pool, a pool is installed on one side edge of the harbor pool, a control panel is installed on one side edge of the harbor pool, which is far away from the pool, a first fan is installed at the top of the harbor pool, a second fan is installed on one side edge of the harbor pool, which is far away from the first fan, a third fan is installed on one side edge of the harbor pool, which is far away from the first fan and the second fan, a fan cover is installed on one side edge of the first fan, which is close to the harbor pool, of the second fan and the third fan, a plurality of sensors are evenly installed inside the harbor pool, water level scales are symmetrically installed between the sensors inside the harbor pool and positioned in the middle of the sensors, a wave generator is installed on one side of the harbor pool, which is close to the control panel, a transverse plate is installed on one side, moving mechanism is all installed with the bottom at the top of diaphragm, just moving mechanism keeps away from the one end of diaphragm all with the harbor pond is connected, the bottom in harbor pond is close to the drain pump is installed to a side in pond, the drain pipe is installed to the one end of drain pump, just the drain pipe is kept away from the one end of drain pump runs through and extends to the inboard side in pond, the inside in pond is close to the intake pump is installed to a side bottom in harbor pond, the inlet tube is installed to the one end of intake pump, just the inlet tube is kept away from the one end of intake pump runs through and extends to the inside bottom in harbor pond, a plurality of bracing pieces are evenly installed to the bottom in harbor pond, the supporting shoe is all installed on the bottom quadrangle.

Preferably, the control panel is provided with a control switch and a fan speed regulator.

Preferably, the first fan, the second fan and the third fan are symmetrically provided with fixing rods, and the other ends of the fixing rods are fixedly connected with the harbor basin.

Preferably, the movable mechanism comprises a connecting block, and the connecting block is fixedly connected with the transverse plate.

Preferably, the connecting rod is installed to the bottom of connecting block, motor one is installed to the bottom of connecting rod, just the gear is all installed at the both ends of motor one.

Preferably, movable grooves are formed in the harbor basin and in positions corresponding to the first motor, the bottom ends of the movable grooves are matched with the first motor, and the top ends of the movable grooves are matched with the connecting rod.

Preferably, tooth sockets matched with the gears are formed in the positions, corresponding to the gears, in the movable grooves.

Preferably, movable clamping blocks are mounted at the bottom of the connecting block and located on two sides of the connecting rod, and clamping grooves matched with the movable clamping blocks are formed in the positions, corresponding to the movable clamping blocks, on the harbor basin.

As preferred, the inside of harbor basin just is located the drain pump with the outside of inlet tube installs the grid screen panel, the grid screen panel is kept away from one side edge of drain pump installs the bar shaped plate, the bar shaped plate is kept away from the one end of grid screen panel with the inner wall fixed connection in harbor basin, evenly install a plurality of motor two on the bar shaped plate, the outside limit of motor two is all scribbled and is equipped with waterproof coating, the dwang is installed to the bottom of motor two, and the bottom of dwang all runs through and extends to the bottom below of bar shaped plate, stirring rod one is all installed to one side edge bottom of dwang, stirring rod two is all installed to the top that one side edge of stirring rod one was kept away from to the dwang, and stirring rod one with stirring rod two's bottom all installs a plurality of branch, the inside bottom symmetry of harbor basin has seted up the silt, arrange the silt valve all to install in the bottom of arranging the silt mouth, just arrange the bottom of silt valve and all install the coupling.

A harbor basin test method is characterized by comprising the following steps:

the method comprises the following steps: debugging, namely debugging the start and stop of the switches of the fan I, the fan II, the fan III, the wave generator, the camera, the motor I, the drainage pump and the water inlet pump through the control panel to ensure that all the components can carry out normal start and stop operation;

step two: testing the wind wave parameters and the water flow parameters under the action of different wind speeds under the regular waves and different wind directions;

setting wave height parameters, period parameters and stability parameters of the wave making machine through the control panel, enabling the wave making machine to generate waves with regularity, then starting the first fan, setting the first fan into a low wind mode through a fan speed regulator, driving the camera to move and shoot through the movable mechanism, and simultaneously matching with the action of the sensor to obtain the wave parameters and the water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine through the control panel, enabling the wave making machine to generate waves with regularity, then starting the second fan, setting the second fan into a low wind mode through a fan speed regulator, driving the camera to move and shoot through the movable mechanism, and simultaneously matching with the action of the sensor to obtain the wave parameters and the water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine through the control panel, enabling the wave making machine to generate waves with regularity, then starting the third fan, setting the third fan into a low wind mode through a fan speed regulator, driving the camera to move and shoot through the movable mechanism, and simultaneously matching with the action of the sensor to obtain the wave parameters and the water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step three: testing the wave parameters and the water flow parameters under the action of different wind speeds under the irregular waves and different wind directions;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave generator through the control panel, enabling the wave generator to generate waves with irregularity, then starting the first fan, setting the first fan into a low wind mode through a fan speed regulator, driving the camera to carry out moving shooting through the movable mechanism, and simultaneously matching with the action of the sensor to obtain a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave generator through the control panel, enabling the wave generator to generate waves with irregularity, then starting the second fan, setting the second fan into a low wind mode through a fan speed regulator, driving the camera to perform moving shooting through the movable mechanism, and simultaneously matching with the action of the sensor to acquire a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave generator through the control panel, enabling the wave generator to generate waves with irregularity, then starting the third fan, setting the third fan into a low wind mode through a fan speed regulator, driving the camera to perform moving shooting through the movable mechanism, and simultaneously matching with the action of the sensor to acquire a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step four: processing and integrating the parameters obtained in the steps;

step five: and (5) making a graph according to the data after the processing and the integration, and displaying the graph to finish the test.

Compared with the prior art, the invention has the advantages and positive effects that:

1. the method and the device well solve the problem of how to better perform the simulation test of the harbor basin, so that when people simulate the harbor basin, the storm parameters and the water flow parameters under different conditions cannot be tested, the quality of the harbor basin is influenced, and the use requirements of people cannot be better met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic diagram of an architecture according to an embodiment of the present invention;

FIG. 2 is a schematic view of a partial bottom view of an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a movable mechanism according to an embodiment of the present invention;

fig. 4 is a flow chart of a method according to an embodiment of the present invention.

In the figure:

1. a harbor basin; 2. a pool; 3. a control panel; 4. a first fan; 5. a second fan; 6. a third fan; 7. a fan housing; 8. a sensor; 9. a water level scale; 10. a wave making machine; 11. a transverse plate; 12. a camera; 13. a movable mechanism; 14. draining pump; 15. a drain pipe; 16. a water inlet pump; 17. a water inlet pipe; 18. fixing the rod; 19. connecting blocks; 20. a connecting rod; 21. a first motor; 22. a gear; 23. a movable groove; 24. a tooth socket; 25. a movable clamping block; 26. a card slot; 27. a support bar; 28. a support block; 29. a grille guard; 30. a strip plate; 31. a second motor; 32. rotating the rod; 33. a first stirring rod; 34. a stirring rod II; 35. a strut; 36. a sludge discharge port; 37. a sludge discharge valve; 38. there are pipe joints.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, the present invention will be further described with reference to the accompanying drawings and examples. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

The invention is further described with reference to the following figures and specific examples.

In a first embodiment, as shown in fig. 1 to 3, a harbor basin simulation device according to an embodiment of the present invention includes a harbor basin 1, a basin 2 is installed on one side of the harbor basin 1, a control panel 3 is installed on one side of the harbor basin 1 away from the basin 2, under the action of the control panel 3, the harbor basin can be better controlled during a simulation test so as to be better convenient for people to use, a first fan 4 is installed on the top of the harbor basin 1, a second fan 5 is installed on one side of the harbor basin 1 away from the first fan 4, a third fan 6 is installed on one side of the harbor basin 1 away from the control panel 3 and perpendicular to the first fan 4 and the second fan 5, a fan cover 7 is installed on one side of the first fan 4 and the second fan 5 and one side of the third fan 6 close to the harbor basin 1, under the action of the first fan 4 and the second fan 5 and the third fan 6, the device can generate wind power from different directions so as to better perform simulation test operation, a plurality of sensors 8 are uniformly installed in the harbor basin 1, the sensors 8 can perform sensing record on the simulated condition during the simulation test so as to better obtain a parameter change structure of the test, water level scales 9 are symmetrically installed in the harbor basin 1 and between the sensors 8, a wave generator 10 is installed in the harbor basin 1 and on one side far away from the control panel 3, a transverse plate 11 is installed on one side close to the control panel 3 on the harbor basin 1, a plurality of cameras 12 are uniformly installed on the transverse plate 11, the cameras 12 can record the wave condition of the water surface so as to better obtain the simulation test result, and movable mechanisms 13 are installed at the top and the bottom of the transverse plate 11, and one end of the movable mechanism 13 far away from the transverse plate is connected with the harbor basin 1, a drain pump 14 is installed at one side edge of the bottom of the harbor basin 1 close to the water basin 2, a drain pipe 15 is installed at one end of the drain pump 14, one end of the drain pipe 15 far away from the drain pump 14 penetrates and extends to the inner side edge of the water basin 2, a water inlet pump 16 is installed at one side edge bottom end of the water basin 2 close to the harbor basin 1, a water inlet pipe 17 is installed at one end of the water inlet pump 16, one end of the water inlet pipe 17 far away from the water inlet pump 16 penetrates and extends to the inner bottom end of the harbor basin 1, and water conveying and water draining can be better performed on the harbor basin 1 under the interaction of the drain pump 14, the drain pipe 15, the water inlet pump 16 and the water inlet pipe 17, so as to better perform, a plurality of bracing pieces 27 are evenly installed to the bottom of harbor pond 1, supporting shoe 28 is all installed on the bottom quadrangle limit of pond 2, through bracing piece 27 with supporting shoe 28 can make respectively harbor pond 1 and pond 2 reaches good stability to the analogue test operation that carries on that people can be better of being convenient for, and then the user demand that satisfies people that can be better of being convenient for.

In the second embodiment, as shown in fig. 1, a control switch and a fan speed regulator are installed on the control panel 3; people can be convenient for better control when using to be convenient for can be better satisfy people's user demand.

In a third embodiment, as shown in fig. 1, fixing rods 18 are symmetrically installed on outer sides of the first fan 4, the second fan 5 and the third fan 6, and the other ends of the fixing rods 18 are fixedly connected with the harbor basin 1; through the dead lever 18 can make fan one 4 with fan two 5 and fan three 6 reach good stability to be convenient for can be better carry out the analogue test operation, and then be convenient for can be better satisfy people's user demand.

In a fourth embodiment, as shown in fig. 1 and 3, the movable mechanism 13 includes a connecting block 19, and the connecting block 19 is fixedly connected with the transverse plate 11; the bottom of the connecting block 19 is provided with a connecting rod 20, the bottom of the connecting rod 20 is provided with a first motor 21, and two ends of the first motor 21 are provided with gears 22; movable grooves 23 are formed in the harbor basin 1 at positions corresponding to the first motor 21, the bottom ends of the movable grooves 23 are matched with the first motor 21, and the top ends of the movable grooves 23 are matched with the connecting rod 20; tooth grooves 24 matched with the gear 22 are formed in the movable groove 23 at positions corresponding to the gear 22; movable clamping blocks 25 are respectively arranged at the bottom of the connecting block 19 and at two sides of the connecting rod 20, and clamping grooves 26 matched with the movable clamping blocks 25 are respectively arranged at positions on the harbor basin 1 corresponding to the movable clamping blocks 25; when the camera is used, the first motor 21 interacts with the gear 22, the movable groove 23 interacts with the tooth groove 24, the movable mechanism 13 can be driven to move the camera 12 on the transverse plate 11 better, so that test results can be collected better, and the movable clamping block 25 interacts with the clamping groove 26, so that the movable mechanism 13 can be ensured to achieve good stability in the moving process, and the use requirements of people can be met better.

Embodiment five, as shown in fig. 2, the inside of harbour basin 1 just is located drain pump 14 with the grid screen 29 is installed in the outside of inlet tube 17, grid screen 29 keeps away from drain pump 14's a side installs strip shaped plate 30, strip shaped plate 30 keeps away from grid screen 29's one end with harbour basin 1's inner wall fixed connection, evenly install two 31 of a plurality of motors on the strip shaped plate 30, the outside limit of two 31 of motors is all scribbled and is equipped with waterproof coating, dwang 32 is installed to two 31 of motors's bottom, just the bottom of dwang 32 all runs through and extends to the bottom below of strip shaped plate 30, stirring rod 33 is all installed to a side bottom of dwang 32, dwang 32 keeps away from the top of a side of stirring rod 33 all installs stirring rod two 34, just a plurality of branches 35 are all installed to one 33 of stirring rod with the bottom of stirring rod two 34, a sludge discharge port 36 is symmetrically formed in the bottom end of the interior of the harbor basin 1, sludge discharge valves 37 are mounted at the bottoms of the sludge discharge ports 36, and pipe joints 38 are mounted at the bottoms of the sludge discharge valves 37; in the process of analogue test, when needs row silt simulation, at first pour a certain amount of earth into the inside of harbour pond 1, treat silt deposit and form and pile up the back, will water in the harbour pond 1 is extracted partly, only leaves the water that occupies the harbour pond 1 bottom, then starts two 31 motors drive under two 31 motors's the effect dwang 32 rotates, dwang 32 drives stirring rod 33 with stirring rod two 34 rotates, stirring rod 33 with stirring rod two 34 drives respectively branch 35 rotates stirring rod 33 with stirring rod two 33 and branch 35 interact down stirs the accumulational silt of deposiing, treats to deposit accumulational silt and mixes the back with remaining water silt, opens row valve 37, discharges the muddy water mixture, thereby be convenient for can be better carry out the analogue test of the desilting operation of harbor basin, and then be convenient for can be better satisfy people's user demand.

Sixth embodiment, as shown in fig. 4, a harbor basin testing method according to an embodiment of the present invention is characterized by comprising the following steps:

the method comprises the following steps: debugging, namely debugging the start and stop of the switches of the first fan 4, the second fan, the third fan 6, the wave generator 10, the camera 12, the first motor 21, the drainage pump 14 and the water inlet pump 16 through the control panel 3 to ensure that all the components can be normally started and stopped;

step two: testing the wind wave parameters and the water flow parameters under the action of different wind speeds under the regular waves and different wind directions;

setting wave height parameters, period parameters and stability parameters of the wave making machine 10 through the control panel 3, enabling the wave making machine 10 to generate waves with regularity, then starting the fan I4, setting the fan I4 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine 10 through the control panel 3, enabling the wave making machine 10 to generate waves with regularity, then starting the second fan 5, setting the second fan 5 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine 10 through the control panel 3, enabling the wave making machine 10 to generate waves with regularity, then starting the third fan 6, setting the third fan 6 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step three: testing the wave parameters and the water flow parameters under the action of different wind speeds under the irregular waves and different wind directions;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave maker 10 through the control panel 3, so that the wave maker 10 generates irregular waves, then starting the fan I4, setting the fan I4 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting the parameters of the wave height, the spectrum peak period, the energy and the repeatability of the wave generator 10 through the control panel 3, so that the wave generator 10 generates irregular waves, then starting the second fan 5, setting the second fan 5 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining the parameters of the wind waves and the water flow; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting the parameters of the wave height, the spectrum peak period, the energy and the repeatability of the wave generator 10 through the control panel 3, so that the wave generator 10 generates irregular waves, then starting the fan III 6, setting the fan III 6 into a low wind mode through a fan speed regulator, driving the camera 12 to move and shoot through the movable mechanism 13, and simultaneously matching with the action of the sensor 8, obtaining the parameters of the wind waves and the water flow; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step four: processing and integrating the parameters obtained in the steps;

step five: and (5) making a graph according to the data after the processing and the integration, and displaying the graph to finish the test.

Generally, the method and the device well solve the problem of how to better perform the simulation test of the harbor basin, so that when people perform the simulation of the harbor basin, the wind wave parameters and the water flow parameters under different conditions cannot be tested, the quality of the harbor basin is influenced, and the use requirements of people cannot be better met.

The present invention can be easily implemented by those skilled in the art from the above detailed description. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the basis of the disclosed embodiments, a person skilled in the art can combine different technical features at will, thereby implementing different technical solutions.

Claims (9)

1. The port pool simulation device is characterized by comprising a port pool (1), a pool (2) is installed on one side edge of the port pool (1), and a control panel (3) is installed on one side edge of the pool (2) and is kept away from the port pool (1).

2. The harbor basin simulation device according to claim 1, wherein a first fan (4) is installed at the top of the harbor basin (1), a second fan (5) is installed at one side of the harbor basin (1) far away from the first fan (4), a third fan (6) is installed at one side of the harbor basin (1) far away from the control panel (3) and at one side perpendicular to the first fan (4) and the second fan (5), a fan cover (7) is installed at one side of the first fan (4), the second fan (5) and the third fan (6) close to the harbor basin (1), a plurality of sensors (8) are evenly installed inside the harbor basin (1), water level scales (9) are symmetrically installed between the sensors (8), a wave generator (10) is installed inside the harbor basin (1) and at one side far away from the control panel (3), diaphragm (11) is installed to one side that is close to on harbor pond (1) control panel (3), evenly install a plurality of camera (12) on diaphragm (11), moving mechanism (13) are all installed to the top and the bottom of diaphragm (11), just moving mechanism (13) are kept away from the one end of diaphragm all with harbor pond (1) is connected, the bottom of harbor pond (1) is close to one side of pond (2) installs drain pump (14), drain pipe (15) is installed to the one end of drain pump (14), just drain pipe (15) keep away from the one end of drain pump (14) run through and extend to the inboard side of pond (2), the inside of pond (2) is close to one side bottom of harbor pond (1) installs intake pump (16), inlet tube (17) is installed to the one end of intake pump (16), one end, far away from the water inlet pump (16), of the water inlet pipe (17) penetrates through and extends to the bottom end of the interior of the harbor basin (1), a plurality of support rods (27) are uniformly installed at the bottom of the harbor basin (1), and supporting blocks (28) are installed on four corner edges of the bottom of the basin (2);

the inside of harbour pond (1) just is located drain pump (14) with grid screen panel (29) is installed in the outside of inlet tube (17), grid screen panel (29) are kept away from a side edge of drain pump (14) installs strip shaped plate (30), strip shaped plate (30) are kept away from the one end of grid screen panel (29) with the inner wall fixed connection of harbour pond (1), evenly install a plurality of motor two (31) on strip shaped plate (30), the outside limit of motor two (31) all is scribbled and is equipped with waterproof coating, dwang (32) are installed to the bottom of motor two (31), just the bottom of dwang (32) all runs through and extends to the bottom below of strip shaped plate (30), stirring rod one (33) is all installed to a side edge bottom of dwang (32), dwang (32) are kept away from stirring rod two (34) are all installed on the top of a side edge of stirring rod (33), just stirring pole one (33) with a plurality of branches (35) are all installed to the bottom of stirring pole two (34), row's silt mouth (36) have been seted up to the inside bottom symmetry of harbor basin (1), row's silt valve (37) are all installed to the bottom of arranging silt mouth (36), just pipe joint (38) are all installed to the bottom of arranging silt valve (37), install control switch and fan speed regulator on control panel (3).

3. The harbor basin simulation device and the test method thereof according to claim 2, wherein the first fan (4), the second fan (5) and the third fan (6) are symmetrically provided with fixing rods (18) at the outer sides, and the other ends of the fixing rods (18) are fixedly connected with the harbor basin (1).

4. The harbor basin simulator according to claim 2, characterized in that said movable mechanism (13) comprises connecting blocks (19), and said connecting blocks (19) are fixedly connected with said cross plate (11).

5. The harbor basin simulation device according to claim 4, wherein the bottom of the connecting block (19) is installed with a connecting rod (20), the bottom of the connecting rod (20) is installed with a first motor (21), and gears (22) are installed at both ends of the first motor (21).

6. The harbor basin simulation device according to claim 5, wherein the inside of the harbor basin (1) corresponding to the first motor (21) is provided with a movable groove (23), the bottom end of the movable groove (23) is adapted to the first motor (21), and the top end of the movable groove (23) is adapted to the connecting rod (20).

7. The harbor basin simulation device according to claim 6, wherein the movable groove (23) is provided with tooth grooves (24) corresponding to the gear (22) at the positions corresponding to the gear (22).

8. The harbor basin simulation device according to claim 7, wherein movable blocks (25) are installed at the bottom of the connecting block (19) and at two sides of the connecting rod (20), and slots (26) matched with the movable blocks (25) are formed at positions on the harbor basin (1) corresponding to the movable blocks (25).

9. A method for testing a port basin according to any of claims 2-8, characterized by the steps of:

the method comprises the following steps: debugging, namely debugging the start and stop of the first fan (4), the second fan, the third fan (6), the wave generator (10), the camera (12), the first motor (21), the drainage pump (14) and the water inlet pump (16) through the control panel (3) to ensure that all parts can be normally started and stopped;

step two: testing the wind wave parameters and the water flow parameters under the action of different wind speeds under the regular waves and different wind directions;

setting wave height parameters, period parameters and stability parameters of the wave making machine (10) through the control panel (3), enabling the wave making machine (10) to generate waves with regularity, then starting the fan I (4), setting the fan I (4) into a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine (10) through the control panel (3), enabling the wave making machine (10) to generate waves with regularity, then starting the second fan (5), setting the second fan (5) into a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting wave height parameters, period parameters and stability parameters of the wave making machine (10) through the control panel (3), enabling the wave making machine (10) to generate waves with regularity, then starting the third fan (6), setting the third fan (6) into a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire wind wave parameters and water flow parameters; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step three: testing the wave parameters and the water flow parameters under the action of different wind speeds under the irregular waves and different wind directions;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave maker (10) through the control panel (3), enabling the wave maker (10) to generate waves with irregularity, then starting the fan I (4), setting the fan I (4) into a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave maker (10) through the control panel (3), enabling the wave maker (10) to generate waves with irregularity, then starting the second fan (5), setting the second fan (5) to be in a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

setting a pseudo wave height parameter, a spectrum peak period parameter, an energy parameter and a repeatability parameter of the wave maker (10) through the control panel (3), enabling the wave maker (10) to generate waves with irregularity, then starting the third fan (6), setting the third fan (6) to be in a low wind mode through a fan speed regulator, driving the camera (12) to move and shoot through the movable mechanism (13), and simultaneously matching with the action of the sensor (8) to acquire a wind wave parameter and a water flow parameter; then, acquiring storm parameters and water flow parameters when regular waves are generated in a medium wind mode and a high wind mode in sequence;

step four: processing and integrating the parameters obtained in the steps;

step five: and (5) making a graph according to the data after the processing and the integration, and displaying the graph to finish the test.

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