CN219349682U - Indoor tide simulation small-sized device - Google Patents

Abstract

The utility model discloses an indoor tide simulation small-sized device, which comprises: the water pump is fixedly arranged in the box body, the water pump comprises two water inlet and outlet ports, a motor and a driving module used for controlling the motor to rotate positively or negatively, the circuit system comprises a power supply and a timer used for controlling a power switch, and the water pump is electrically connected with the power supply. The device is simple, easy and convenient to operate, convenient to overhaul, capable of reducing investment of manpower, material resources and time, reducing experimental deviation caused by manual force and time control, improving accuracy and scientificity of experimental results, and realizing intelligent zero-manual tidal rise and tidal fall.

Description

Indoor tide simulation small-sized device

Technical Field

The utility model relates to the technical field of marine environment simulation, in particular to an indoor tide simulation small-sized device.

Background

In the research of the fields of ecology, biology, oceanography and the like, partial experiments need to simulate the growth environment of the marine intertidal animals and plants or the erosion and accumulation conditions of the intertidal sediments so as to ensure the normal development of the experiments. Under the traditional technology, a beaker and a water ladle are generally used for simulating the indoor tidal environment, the tide rising and falling are manually simulated, and the influence effect of rising tide and falling tide on the inter-tidal zone environment is realized by controlling the artificial strength.

The traditional tide simulation steps are as follows: firstly, designing the flood tide time, then injecting a proper amount of seawater into a simulation experiment basin by using a container (such as a beaker) at a set flood tide time point, and repeating the steps until a proper amount of water is obtained; simulating a damping environment at a set damping time point, and manually scooping water in a simulation experiment box by using a container; the above manual simulation of the tidal current rise and fall operation takes about 20 minutes/time. Taking the simulation of the semi-daily tide as an example, the tide rise and fall 2 times in 24 hours a day, namely, the tide rise and fall 1 time in 12 hours, and the manual operation is carried out about 1 time in 6 hours, and the manual operation is carried out 4 times a day, and the total time consumption is about 80 minutes in 24 hours. The traditional manual operation needs to be operated for 4 times a day, so that the time consumption is long, the energy consumption is large, the time interval is too long, and the rest time of an experimenter can influence the accuracy of the fluctuation tide simulation and influence the experimental effect.

In addition, the indoor simulation experiment period is long, and in the artificial simulation tidal process, the artificial force such as watering and pouring steps is not well controlled in time control accuracy, so that experimental deviation can be caused. To sum up, (1) traditional manual operation needs to operate 4 times a day, consumes long time, consumes much energy, and is overlong in time interval, and experimenters' rest time can influence the accuracy of fluctuation tide simulation, influences experimental effect. (2) The indoor simulation experiment period is long, and in the artificial simulation tidal process, the artificial force such as watering and pouring steps is not well controlled in time control accuracy, so that experimental deviation can be caused. (3) The manual operation can damage plants and interfere the normal growth of the plants. There is an urgent need to find a small-sized device for indoor tidal simulation that can be accurately controlled.

The Chinese patent 'a tide simulation measurement and control system and a measurement and control method thereof' discloses a tide simulation measurement and control system and a measurement and control method thereof, but cannot simulate in real time according to tide actual measurement data; the Chinese patent 'real-time tidal simulation device' provides a real-time tidal simulation device, which comprises a controller, a liquid level sensor, an uplink water suction pump and a downlink water discharge pump, wherein the device has a complex structure and is not beneficial to operation. Therefore, there is an urgent need to find a small-sized device for simulating the tide in a room, which has a simple structure and is convenient to operate.

Disclosure of Invention

Aiming at the prior art problems, the utility model aims to provide an indoor tide simulation small-sized device which is simple, easy and convenient to operate and convenient to overhaul; the investment of manpower, material resources and time can be reduced, experimental deviation caused by the magnitude of the artificial force and time control is reduced, the accuracy and scientificity of experimental results are improved, and intelligent zero artificial tidal rise and tidal fall are realized.

The above object of the present utility model is achieved by the following technical scheme:

an indoor tidal simulation mini-device comprising: the water pump is fixedly arranged in the box body, the water pump comprises two water inlet and outlet ports, a motor and a driving module used for controlling the motor to rotate positively or negatively, the circuit system comprises a power supply and a timer used for controlling a power switch, and the water pump is electrically connected with the power supply.

The utility model mainly comprises a circuit system, a water pump and a box body, wherein the water pump is provided with a driving module for controlling the forward rotation or the reverse rotation of a motor, two ends of the water pump are respectively connected into a tide basin and a simulation experiment basin, and water flow is guided to flow from the tide basin to the simulation experiment basin or from the simulation experiment basin to the tide basin by controlling the forward rotation driving of the water pump, so that the simulated tide rising and falling are realized, and intelligent zero manual tide rising and falling are realized; in addition, the circuit system also comprises a timer, the timer is used for respectively controlling the communication between the corresponding water pump and the power supply, an experimenter can set specific time by taking a specific experimental scheme as a requirement, and the water pump is communicated with the power supply at the specific time, so that water inlet or water outlet of the water pump is realized. The utility model is simple, easy and convenient to operate and convenient to overhaul; the investment of manpower, material resources and time can be reduced, experimental deviation caused by the magnitude of artificial force and time control is reduced, the accuracy and scientificity of experimental results are improved, and intelligent zero artificial tidal rise and tidal fall are realized.

Preferably, the water pump is a miniature direct current water pump. The device is mainly applied to small indoor simulation experiments, and the miniature direct-current water pump has the advantages of small volume, high efficiency and low power consumption; the miniature direct current water pump has low noise, the noise is lower than 35 dB, the power is smaller by a little and even can reach below 30 dB, the silencing effect is almost achieved, and the noise pollution to the surrounding environment is avoided when the tide is simulated indoors to work.

Preferably, the water pump is provided with at least two. Through setting up multiunit water pump in the box, experimenter not only can control multiunit simulation experiment, can also control the intensity of flood tide and ebb tide, simulate different areas, different grade type flood tide and ebb tide.

Further, in order to more appropriately simulate the rising/falling tide speed and cost consideration, the water pump may be preferably provided in two.

Preferably, the circuit system is arranged outside the box body, and a through hole is formed in the box body and comprises a power supply hole and a water pipe hole. When the inside of the box leaks due to the damage of the water pump, the circuit system is arranged outside the box, so that the short circuit can be avoided.

Preferably, the power supply hole and the water pipe hole are provided on opposite sides of the case.

Preferably, a power interface of the water pump is electrically connected with the power supply through the power hole.

Preferably, two water inlets and outlets of the water pump are connected with pipelines, and the pipelines are respectively connected with the tide basin and the simulation experiment basin through the water pipe holes. When the tide is to be controlled, the pipeline connected with the water pump and the tide basin is a water inlet pipeline, the pipeline connected with the water pump and the simulation experiment basin is a water outlet pipeline, and the water pump guides water flow to flow from the tide basin to the simulation experiment basin; when the tide is required to be controlled, the water pump is connected with the tide basin to form a water outlet pipeline, the water pump is connected with the simulation experiment basin to form a water inlet pipeline, and the water pump guides water flow to flow from the simulation experiment basin to the tide basin.

Preferably, a filtering baffle is arranged in the simulation experiment basin, the simulation experiment basin is divided into a simulation ocean environment area and a pure water body environment area by the filtering baffle, and a pipeline connected with the simulation experiment basin by the water pump is arranged in the pure water body environment area.

The experimental basin is generally used for simulating the growth environment of marine intertidal animals and plants or erosion and accumulation conditions of intertidal sediments required by partial experiments so as to ensure the normal development of the experiments, a filtering baffle plate is arranged in the experimental basin, one side of the filtering baffle plate is a simulated marine environment area, and the simulated marine environment area comprises various sediments and soil sand grains; the other side of the filtering baffle is a pure water body environment area without sediment interference, sediment or soil sand in the simulated marine environment area can be effectively prevented from entering the pure water body environment area by the arrangement of the filtering baffle, and then the water pipe is blocked, so that the device is damaged.

Preferably, the filter separator may be a glass plate, and the glass plate may be rectangular. An adjusting piece is arranged between the bottom of the glass plate and the simulation experiment basin, and the adjusting piece is used for adjusting the height of the glass plate relative to the simulation experiment basin. More specifically, the adjusting member may be gravel laid on the simulation experiment basin, the glass plate is placed on the gravel, the height of the glass plate is adjusted by adjusting the laying thickness of the gravel, and the arrangement of the gravel can also reduce the mixing of sediment; in addition, the adjusting piece can also be a guide rail sliding block pair, and the guide rail sliding block pair can flexibly adjust the height of the glass plate.

Preferably, the filter separator may be a mesh-shaped filter plate.

Preferably, the box body is a box body without a top. The design without the top is convenient for the experimenter to observe or overhaul the device. For example, the box may be rectangular, square, etc.

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

(1) The utility model provides an indoor tide simulation small-sized device which is simple in device, simple and convenient to operate and convenient to overhaul; the investment of manpower, material resources and time can be reduced, experimental deviation caused by the magnitude of the artificial force and time control is reduced, the accuracy and scientificity of experimental results are improved, and intelligent zero artificial tidal rise and tidal fall are realized.

(2) By arranging a plurality of groups of water pumps, the experimental personnel can control a plurality of groups of simulation experiments, can control the intensity of the rising tide and the falling tide, and simulate the rising tide and the falling tide in different areas and different types.

(3) According to the utility model, through setting the timer to control the communication between the corresponding water pump and the power supply respectively, an experimenter can set specific time by taking a specific experimental scheme as a requirement, and the water pump is communicated with the power supply at the specific time, so that water inlet or water outlet of the water pump is realized.

Drawings

Fig. 1 is a schematic view of the construction of the indoor tidal simulation mini-apparatus of example 1.

Fig. 2 is a schematic diagram of the water pump in fig. 1.

Fig. 3 is a schematic structural view of the case of fig. 1.

Fig. 4 is a schematic view of the structure of the case of fig. 1 connecting the tidal basin and the simulation experiment basin.

In the figure, 1, a power supply; 2. a timer; 3. a water pump; 31. a water inlet and a water outlet; 4. a case; 5. a power hole; 6. a water pipe hole; 7. simulating an experiment basin; 8. a tidal basin; 9. and (3) filtering the partition board.

Detailed Description

The following examples are illustrative only and are not to be construed as limiting the utility model. For the purpose of better illustrating the present embodiment, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the actual product dimensions. It will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted. The positional relationship described in the drawings are for illustrative purposes only and are not to be construed as limiting the utility model.

Where the description is made with respect to embodiments of the utility model, such terms as "length," "width," "thickness," "height," "longitudinal," "transverse," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used to indicate orientations and positional relationships based on the orientation or positional relationships shown in the relevant drawings, which are merely for purposes of describing the utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be configured and operated in a particular orientation, and therefore the above terms should not be construed as limiting the utility model.

Example 1

As shown in fig. 1 to 3, an indoor tide simulation small-sized device comprises a box body 4, a water pump 3 and a circuit system, wherein the water pump 3 is fixedly arranged on the box body 4, and the water pump 3 comprises two water inlet and outlet ports 31, a motor and a driving module for controlling the motor to rotate forwards or backwards; the box 4 is provided with a through hole, the circuit system comprises a power supply 1 and a timer 2 for controlling the power supply 1 to be switched on and off, and the water pump 3 is electrically connected with the power supply 1.

In the present embodiment, the case 4 is a case 4 without a roof, more specifically, the case 4 is rectangular. The design without the top is convenient for the experimenter to observe or overhaul the device.

In this embodiment, the circuit system is disposed outside the case 4, the through hole on the case 4 includes a power hole 5 and a water pipe hole 6, the power hole 5 and the water pipe hole 6 are respectively provided with two, and the power hole 5 and the water pipe hole 6 are disposed on opposite sides of the case 4.

In this embodiment, the water pump 3 is a micro direct current water pump. The miniature direct current water pump has the advantages of small volume, high efficiency and low power consumption, and the miniature direct current water pump has low noise, the noise is lower than 35 db, the power is small and even can reach below 30 db, the mute effect is almost achieved, and the noise pollution to the periphery is avoided when the miniature direct current water pump works in an indoor simulated tide.

In the present embodiment, the water pump 3 is provided with two. The power interfaces of the two water pumps 3 are respectively opposite to the two power holes 5, and the two water inlet and outlet ports 31 of the two water pumps 3 are respectively opposite to the two water pipe holes 6.

In this embodiment, the power interface of the water pump 3 is electrically connected to the power source 1 through the corresponding power hole 5 on the case 4.

As shown in fig. 4, in the present embodiment, two water inlets 31 of the water pump 3 are connected with pipes, which are connected with the tidal basin 8 and the simulation experiment basin 7 through water pipe holes 6, respectively. More specifically, when the tide is to be controlled, the water pump 3 is connected to the tide basin 8 to be a water inlet, the water pump 3 is connected to the simulation experiment basin 7 to be a water outlet, and the water pump 3 guides the water flow from the tide basin 8 to the simulation experiment basin 7. When the tide is to be controlled, the water pump 3 is connected with the tide basin 8 to form a water outlet, the water pump 3 is connected with the simulation experiment basin 7 to form a water inlet, and the water pump 3 guides water flow to flow from the simulation experiment basin 7 to the tide basin 8.

In the present embodiment, the timers 2 are provided in two, and the two timers 2 are connected in parallel to the same power supply 1.

In this embodiment, the specific working principle of the device is as follows: the utility model adopts the water pump 3 for controlling the motor forward or reverse driving module, the two ends of the water pump 3 are respectively connected with the tide basin 8 and the simulation experiment basin 7, and the water flow is guided to flow from the tide basin 8 to the simulation experiment basin 7 or from the simulation experiment basin 7 to the tide basin 8 by controlling the forward or reverse driving of the water pump 3, thereby realizing the simulation of rising tide and falling tide and realizing intelligent zero manual rising tide falling; in addition, the timer 2 is further adopted in the circuit system of the device, the timer 2 is used for respectively controlling the communication between the corresponding water pump 3 and the power supply 1, an experimenter can set specific time through the timer 2 according to a specific experimental scheme, the water pump 3 is communicated with the power supply 1 at the specific time, and then water inlet or water outlet of the water pump 3 is realized. The utility model has the advantages of simplicity, simple operation, convenient maintenance, reduced investment of manpower, material resources and time, reduced experimental deviation caused by the magnitude of the artificial force and time control, improved accuracy and scientificity of experimental results, and realization of intelligent zero-artificial tidal rise and fall.

Example 2

As shown in fig. 1 to 3, an indoor tide simulation small-sized device comprises a box body 4, a water pump 3 and a circuit system, wherein the water pump 3 is fixedly arranged on the box body 4, and the water pump 3 comprises two water inlet and outlet ports 31, a motor and a driving module for controlling the motor to rotate forwards or backwards; the box 4 is provided with a through hole, the circuit system comprises a power supply 1 and a timer 2 for controlling the power supply 1 to be switched on and off, and the water pump 3 is electrically connected with the power supply 1.

In the present embodiment, the case 4 is a case 4 without a roof, more specifically, the case 4 is square. The design without the top is convenient for the experimenter to observe or overhaul the device.

In this embodiment, the circuit system is disposed outside the case 4, the through hole on the case 4 includes a power hole 5 and a water pipe hole 6, the power hole 5 and the water pipe hole 6 are respectively provided with two, and the power hole 5 and the water pipe hole 6 are disposed on opposite sides of the case 4.

In this embodiment, the water pump 3 is a micro direct current water pump 3. The miniature direct current water pump has the advantages of small volume, high efficiency and low power consumption, and the miniature direct current water pump has low noise, the noise is lower than 35 db, the power is small and even can reach below 30 db, the mute effect is almost achieved, and the noise pollution to the periphery is avoided when the miniature direct current water pump works in an indoor simulated tide.

In the present embodiment, the water pump 3 is provided with two. The power interfaces of the two water pumps 3 are respectively opposite to the two power holes 5, and the two water inlet and outlet ports 31 of the two water pumps 3 are respectively opposite to the two water pipe holes 6.

In this embodiment, the power interface of each water pump 3 is electrically connected to the power source 1 through a corresponding power hole 5 on the case 4.

As shown in fig. 4, in the present embodiment, two water inlets 31 of the water pump 3 are connected with pipes, which are connected with the tidal basin 8 and the simulation experiment basin 7 through water pipe holes 6, respectively. More specifically, when the tide is to be controlled, the water pump 3 is connected to the tide basin 8 to be a water inlet, the water pump 3 is connected to the simulation experiment basin 7 to be a water outlet, and the water pump 3 guides the water flow from the tide basin 8 to the simulation experiment basin 7. When the tide is to be controlled, the water pump 3 is connected with the tide basin 8 to form a water outlet, the water pump 3 is connected with the simulation experiment basin 7 to form a water inlet, and the water pump 3 guides water flow to flow from the simulation experiment basin 7 to the tide basin 8.

In this embodiment, a filter baffle 9 is provided in the simulation experiment basin 7, the filter baffle 9 divides the simulation experiment basin 7 into a simulation marine environment area and a pure water body environment area, and a pipe connecting the water pump 3 and the simulation experiment basin 7 is provided in the pure water body environment area. The simulation experiment basin 7 is used for simulating the growth environment of marine intertidal animals and plants or erosion and accumulation conditions of intertidal sediments required by partial experiments, so that the normal development of the experiments is ensured, and the filter baffle 9 is arranged in the simulation experiment basin 7, so that sediments or impurities in the region of the simulated marine environment can be effectively prevented from entering the water inlet and outlet, and the water inlet and outlet are blocked.

In this embodiment, the filter separator 9 is a mesh-like filter plate.

In the present embodiment, the timers 2 are provided in two, and the two timers 2 are connected in parallel to the same power supply 1.

In this embodiment, the specific working principle of the device is as follows: the utility model adopts the water pump 3 for controlling the motor forward or reverse driving module, the two ends of the water pump 3 are respectively connected with the tide basin 8 and the simulation experiment basin 7, and the water flow is guided to flow from the tide basin 8 to the simulation experiment basin 7 or from the simulation experiment basin 7 to the tide basin 8 by controlling the forward or reverse driving of the water pump 3, thereby realizing the simulation of rising tide and falling tide and realizing intelligent zero manual rising tide falling; in addition, the timer 2 is further adopted in the circuit system of the device, the timer 2 is used for respectively controlling the communication between the corresponding water pump 3 and the power supply 1, an experimenter can set specific time through the timer 2 according to a specific experimental scheme, the water pump 3 is communicated with the power supply 1 at the specific time, and then water inlet or water outlet of the water pump 3 is realized. The utility model has the advantages of simplicity, simple operation, convenient maintenance, reduced investment of manpower, material resources and time, reduced experimental deviation caused by the magnitude of the artificial force and time control, improved accuracy and scientificity of experimental results, and realization of intelligent zero-artificial tidal rise and fall.

Example 3

As shown in fig. 1 to 3, an indoor tide simulation small-sized device comprises a box body 4, a water pump 3 and a circuit system, wherein the water pump 3 is fixedly arranged on the box body 4, and the water pump 3 comprises two water inlet and outlet ports 31, a motor and a driving module for controlling the motor to rotate forwards or backwards; the box 4 is provided with a through hole, the circuit system comprises a power supply 1 and a timer 2 for controlling the power supply 1 to be switched on and off, and the water pump 3 is electrically connected with the power supply 1.

In the present embodiment, the case 4 is a case 4 without a roof, more specifically, the case 4 is square. The design without the top is convenient for the experimenter to observe or overhaul the device.

In this embodiment, the circuit system is disposed outside the case 4, the through hole on the case 4 includes a power hole 5 and a water pipe hole 6, the power hole 5 and the water pipe hole 6 are respectively provided with two, and the power hole 5 and the water pipe hole 6 are disposed on opposite sides of the case 4.

In this embodiment, the water pump 3 is a micro direct current water pump 3. The miniature direct current water pump has the advantages of small volume, high efficiency and low power consumption, and the miniature direct current water pump has low noise, the noise is lower than 35 db, the power is small and even can reach below 30 db, the mute effect is almost achieved, and the noise pollution to the periphery is avoided when the miniature direct current water pump works in an indoor simulated tide.

In the present embodiment, the water pump 3 is provided with two. The power supplies of the two water pumps 3 are respectively opposite to the two power holes 5, and the two water inlet and outlet ports 31 of the two water pumps 3 are respectively opposite to the two water pipe holes 6.

In the present embodiment, the power supply of each water pump 3 is electrically connected to the power supply 1 through a corresponding power supply hole 5 on the case 4.

As shown in fig. 4, in the present embodiment, two water inlets 31 of the water pump 3 are connected with pipes, which are connected with the tidal basin 8 and the simulation experiment basin 7 through water pipe holes 6, respectively. More specifically, when the tide is to be controlled, the water pump 3 is connected to the tide basin 8 to be a water inlet, the water pump 3 is connected to the simulation experiment basin 7 to be a water outlet, and the water pump 3 guides the water flow from the tide basin 8 to the simulation experiment basin 7. When the tide is to be controlled, the water pump 3 is connected with the tide basin 8 to form a water outlet, the water pump 3 is connected with the simulation experiment basin 7 to form a water inlet, and the water pump 3 guides water flow to flow from the simulation experiment basin 7 to the tide basin 8.

In this embodiment, a filter baffle 9 is provided in the simulation experiment basin 7, the filter baffle 9 divides the simulation experiment basin 7 into a simulation marine environment area and a pure water body environment area, and a pipe connecting the water pump 3 and the simulation experiment basin 7 is provided in the pure water body environment area. The simulation experiment basin 7 is used for simulating the growth environment of marine intertidal animals and plants or erosion and accumulation conditions of intertidal sediments required by partial experiments, so that the normal development of the experiments is ensured, and the filter baffle 9 is arranged in the simulation experiment basin 7, so that sediments or impurities in the region of the simulated marine environment can be effectively prevented from entering the water inlet and outlet, and the water inlet and outlet are blocked.

In this embodiment, the filter membrane 9 may be a rectangular glass plate, and a layer of gravel is placed between the bottom of the filter membrane 9 and the simulation experiment basin 7, and the filter membrane 9 is placed on the gravel. The arrangement of the gravel can reduce the mixing of sediment.

In the present embodiment, the timers 2 are provided in two, and the two timers 2 are connected in parallel to the same power supply 1.

In this embodiment, the specific working principle of the device is as follows: the utility model adopts the water pump 3 for controlling the motor forward or reverse driving module, the two ends of the water pump 3 are respectively connected with the tide basin 8 and the simulation experiment basin 7, and the water flow is guided to flow from the tide basin 8 to the simulation experiment basin 7 or from the simulation experiment basin 7 to the tide basin 8 by controlling the forward or reverse driving of the water pump 3, thereby realizing the simulation of rising tide and falling tide and realizing intelligent zero manual rising tide falling; in addition, the timer 2 is further adopted in the circuit system of the device, the timer 2 is used for respectively controlling the communication between the corresponding water pump 3 and the power supply 1, an experimenter can set specific time through the timer 2 according to a specific experimental scheme, the water pump 3 is communicated with the power supply 1 at the specific time, and then water inlet or water outlet of the water pump 3 is realized. The utility model has the advantages of simplicity, simple operation, convenient maintenance, reduced investment of manpower, material resources and time, reduced experimental deviation caused by the magnitude of the artificial force and time control, improved accuracy and scientificity of experimental results, and realization of intelligent zero-artificial tidal rise and fall.

It should be noted that the above embodiments are merely for illustrating the technical solution of the present utility model and not for limiting the scope of the present utility model, and that other various changes and modifications can be made by one skilled in the art based on the above description and the idea, and it is not necessary or exhaustive to all embodiments. Any modification, equivalent replacement, improvement, etc. which come within the spirit and principles of the utility model are desired to be protected by the following claims.

Claims (7)

1. An indoor tidal simulation mini-apparatus, comprising:

a case (4);

the water pump (3), the said water pump (3) is fixedly installed in the box (4), the said water pump (3) includes two water inlet and outlet ports (31), electrical machinery and drive module used for controlling the electrical machinery to rotate forward or backward;

the circuit system comprises a power supply (1) and a timer (2) for controlling the switching of the power supply (1), wherein the water pump (3) is electrically connected with the power supply (1);

the circuit system is arranged outside the box body (4), a through hole is formed in the box body (4), and the through hole comprises a power supply hole (5) and a water pipe hole (6);

two water inlet and outlet ports (31) of the water pump (3) are connected with pipelines, and the pipelines are respectively connected with the tide basin (8) and the simulation experiment basin (7) through the water pipe holes (6);

the simulation experiment basin (7) is internally provided with a filtering baffle (9), the filtering baffle (9) divides the simulation experiment basin (7) into a simulation ocean environment area and a pure water body environment area, and a water pump (3) is arranged in the pure water body environment area through a pipeline connected with the simulation experiment basin (7).

2. The indoor tidal simulation miniature apparatus according to claim 1, wherein the water pump (3) is a miniature direct current water pump.

3. An indoor tidal simulation mini-device according to claim 1 or 2, characterized in that the water pump (3) is provided with at least two.

4. The indoor tidal simulation miniature apparatus according to claim 1, wherein the power supply hole (5) and the water pipe hole (6) are provided on opposite sides of the tank body (4).

5. The indoor tidal simulation miniature apparatus according to claim 1, wherein the power interface of the water pump (3) is electrically connected to the power source (1) through the power hole (5).

6. The indoor tide simulation small-sized apparatus according to claim 1, wherein the filtering baffle (9) is a glass plate, an adjusting member is provided between the bottom of the filtering baffle (9) and the simulation experiment basin (7), and the adjusting member is used for adjusting the height of the filtering baffle (9) relative to the simulation experiment basin (7).

7. An indoor tidal simulation mini-device according to claim 1, characterized in that the filter screen (9) is a grid-like filter plate.

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