CN207472876U - Self-loopa river ecological simulates monitoring device and system - Google Patents
Self-loopa river ecological simulates monitoring device and system Download PDFInfo
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- CN207472876U CN207472876U CN201721716020.4U CN201721716020U CN207472876U CN 207472876 U CN207472876 U CN 207472876U CN 201721716020 U CN201721716020 U CN 201721716020U CN 207472876 U CN207472876 U CN 207472876U
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Abstract
The utility model embodiment provides a kind of self-loopa river ecological simulation monitoring device and system.Wherein, water circulation component is connect with visual groove body, and controller is electrically connected with water circulation component, and controller is used to control the working condition of the water circulation component.Hydrodynamic force detection components are set in the visual groove body, and controller is also electrically connected with hydrodynamic force detection components and monitoring terminal respectively.Controller is additionally operable to obtain the data on flows of the water in visual groove body by hydrodynamic force detection components, and the data on flows is fed back to the monitoring terminal, so that the monitoring terminal shows the data on flows.Hydrodynamic condition and the aquatic environment factor can accurately be changed, to obtain the result of the health status of accurately observation or evaluation river ecological environment.It saves and studies time-consuming and manpower and materials.Continuous long-term on-line monitoring can be achieved, ensure the continuity and integrality of experimental data.Have great importance to the research and protection of environment.
Description
Technical field
The utility model is related to Environmental Studies technical fields, and monitoring dress is simulated in particular to self-loopa river ecological
It puts and system.
Background technology
Aquatic organism Large Scale Death event reflects aquatic organism and its existence caused by water body in waters is polluted
Environment is unified entirety, and the two interdependence mutually compensates for, coevolution.Therefore, biobehavioral monitoring becomes river dirt
Dye monitoring, the important means repaired, forecast and evaluated.However, it is realized to monitor this technology using biobehavioral to environment
The assessment of pollution condition, it is necessary first to study biobehavioral and envirment factor variation.
But the water quality parameter variation of practical river water body is difficult control, meanwhile, the aquatic organism in river is influenced by environment
Behavior response also be difficult to accurately monitor.Therefore to carry out experimental study to obtain contaminated river company in river in the wild
Continuous, reliable data and data are unpractical.
Utility model content
The purpose of this utility model is to provide a kind of self-loopa river ecological simulation monitoring device and system, to improve
The above problem.
To achieve these goals, the technical solution that the utility model embodiment uses is as follows:
In a first aspect, the utility model embodiment provides a kind of self-loopa river ecological simulation monitoring device, the dress
It puts including mounting assembly, water circulation component, visual groove body, hydrodynamic force detection components, controller and monitoring terminal, the visual slot
Body is installed on the mounting assembly, and the water circulation component includes the first water inlet and the first water outlet, the visual groove body
Both ends set the second water inlet and the second water outlet respectively, and first water inlet is connect with second water outlet, and described
One water outlet is connect with the second water inlet, the hydrodynamic force detection components be set to second water inlet and the second water outlet it
Between, the controller is electrically connected respectively with the hydrodynamic force detection components, water circulation component and monitoring terminal, the controller
For controlling the working condition of the water circulation component, to realize the flow control to the water in the visual groove body, the control
Device processed is additionally operable to obtain the data on flows of the water in the visual groove body by the hydrodynamic force detection components, and by the flow
Data feedback is to the monitoring terminal, and to show the data on flows by the monitoring terminal, the monitoring terminal is additionally operable to
Control instruction is sent to the controller, to control the working condition of the controller.
Further, described device further includes inlet damper, and the visual groove body includes intake chamber, effluent trough and river master
Slot, second water inlet are located at the intake chamber, and second water outlet is located at the effluent trough, the intake chamber, water outlet
Slot is respectively arranged at the both sides of the river major trough, and inlet damper is set between the intake chamber and the river major trough, described
Inlet damper is set between effluent trough and the river major trough.
Further, the river major trough includes the first slot section and the second slot section, the first slot section and the second slot Duan Lian
It is logical, and form a preset angle between the first slot section and the second slot section.
Further, multiple apopores are set on the inlet damper.
Further, the inlet damper includes telescopic baffle, and the telescopic baffle is worn from the bottom of the visual groove body
Into in the visual groove body, the side walls of the both sides of the telescopic baffle respectively with the visual groove body are connect, described flexible
Baffle is electrically connected with the controller, and the telescopic baffle is used for basis under the control of the controller towards far from the bottom
The side stretching, extension in portion bounces back towards the bottom.
Further, the hydrodynamic force detection components include triangular-notch weir baffle and needle water level gauge, the two of the river major trough
End is respectively provided with triangular-notch weir baffle and needle water level gauge.
Further, the water circulation component includes strainer and electric control valve, first water inlet and the first water outlet
Strainer and electric control valve are both provided with, the strainer is overlapped with electric control valve, the electric control valve and controller electricity
Property connection, the controller is used to control the working condition of the electric control valve.
Further, the visual groove body includes glass groove body, and the glass groove body is spliced to form by organic glass.
Further, described device further includes water-bed ecological artificial layer, the bottom ecological artificial layer be fixed on it is described can
Depending on the bottom of groove body, the bottom ecological artificial layer includes light emulator, thermostat and water speed modulator, the light
Emulator, thermostat and water speed modulator are connect respectively with the controller, and the controller is additionally operable to control the light
The working condition of line emulator, thermostat and water speed modulator, to realize the simulation to a variety of river states.
Second aspect, the utility model embodiment also provide a kind of self-loopa river ecological simulation monitoring system, the system
System include online water quality monitoring instrument and above-mentioned self-loopa river ecological simulation monitoring device, the online water quality monitoring instrument and
The monitoring terminal in the self-loopa river ecological simulation monitoring device is electrically connected, the online water quality monitoring instrument
Test section is set in the visual groove body, and the test section is used to detect the water quality factor number of the water in the visual groove body
According to, and feed back to the monitoring terminal.
Difference with the prior art is that the utility model embodiment provides a kind of self-loopa river ecological simulation monitoring
Apparatus and system.Wherein, the visual groove body is installed on the mounting assembly, the water circulation component include the first water inlet with
First water outlet, the both ends of the visual groove body set the second water inlet and the second water outlet respectively, first water inlet with
The second water outlet connection, first water outlet are connect with the second water inlet, and the controller and water circulation component are electrical
Connection, the controller are used to control the working condition of the water circulation component, to realize to the water in the visual groove body
Flow control is simulated so as to fulfill to the streamflow regime in true river, is between biobehavioral and envirment factor variation
The research of relationship is provided convenience.The hydrodynamic force detection components are set between second water inlet and the second water outlet,
The controller is electrically connected respectively with the hydrodynamic force detection components and the monitoring terminal.The controller is additionally operable to pass through
The hydrodynamic force detection components obtain the data on flows of the water in the visual groove body, and the data on flows are fed back to described
Monitoring terminal, so that the data on flows is shown by the monitoring terminal.It is seen relative in the relevant technologies in true river
For the mode of survey, it can more accurately change hydrodynamic condition and the aquatic environment factor, to obtain accurately observation or evaluation
The result of the health status of river ecological environment.It saves and studies time-consuming and manpower and materials.Continuous long-term on-line monitoring can be achieved, protect
Demonstrate,prove the continuity and integrality of experimental data.Have great importance to the research and protection of environment.
For the above-mentioned purpose of the utility model, feature and advantage is enable to be clearer and more comprehensible, preferred embodiment cited below particularly, and
Attached drawing appended by cooperation, is described in detail below.
Description of the drawings
It, below will be to use required in embodiment in order to illustrate more clearly of the technical solution of the utility model embodiment
Attached drawing be briefly described, it should be understood that the following drawings illustrates only some embodiments of the utility model, therefore should not be by
Regard the restriction to range as, for those of ordinary skill in the art, without creative efforts, may be used also
To obtain other relevant attached drawings according to these attached drawings.
Fig. 1 shows that the structure of a kind of self-loopa river ecological simulation monitoring device that the utility model embodiment provides is shown
It is intended to.
Fig. 2 shows the schematic diagrames for the water-bed ecological artificial layer that the utility model embodiment provides.
Fig. 3 shows another portion of a kind of self-loopa river ecological simulation monitoring device that the utility model embodiment provides
Divide schematic diagram.
Fig. 4 shows the signal of a kind of self-loopa river ecological simulation monitoring system that the utility model embodiment provides
Figure.
Icon:100- self-loopas river ecological simulates monitoring device;10- mounting assemblies;20- water circulation components;30- is visual
Groove body;31- intake chambers;32- effluent troughs;33- rivers major trough;331- the first slot sections;332- the second slot sections;The second water inlets of 34-;
The second water outlets of 35-;40- hydrodynamic force detection components;50- inlet dampers;60- bottoms ecological artificial layer;61- light emulators;
62- thermostats;63- water speed modulators;70- controllers;80- monitoring terminals;The simulation monitoring of 200- self-loopas river ecological
System;The online water quality monitoring instruments of 201-.
Specific embodiment
Below in conjunction with attached drawing in the utility model embodiment, the technical scheme in the embodiment of the utility model is carried out clear
Chu is fully described by, it is clear that the described embodiments are only a part of the embodiments of the utility model rather than whole realities
Apply example.The component of the utility model embodiment being usually described and illustrated herein in the accompanying drawings can be come with a variety of different configurations
Arrangement and design.Therefore, the detailed description of the embodiment of the utility model provided in the accompanying drawings is not intended to limit below
Claimed the scope of the utility model, but it is merely representative of the selected embodiment of the utility model.Based on the utility model
Embodiment, those skilled in the art's all other embodiments obtained under the premise of creative work is not made, all
Belong to the range of the utility model protection.
It should be noted that:Similar label and letter represents similar terms in following attached drawing, therefore, once a certain Xiang Yi
It is defined in a attached drawing, does not then need to that it is further defined and explained in subsequent attached drawing.It is meanwhile new in this practicality
In the description of type, term " first ", " second " etc. are only used for distinguishing description, and it is not intended that indicating or implying relatively important
Property.
First embodiment
Fig. 1 is please referred to, Fig. 1 shows a kind of schematic diagram of self-loopa river ecological simulation monitoring device 100.The self-loopa
River ecological simulation monitoring device 100 includes mounting assembly 10, water circulation component 20, visual groove body 30, hydrodynamic force detection components
40.The visual groove body 30 is installed on the mounting assembly 10, and the water circulation component 20 is connect with visual groove body 30.Hydrodynamic force
Detection components 40 are set in visual groove body 30.
Above-mentioned mounting assembly 10 is made of shaped steel.It specifically, can be according to wanted simulating riverway substrate, water body weight and water
Pressure selects shaped steel size to ensure the safe handling of device.
Above-mentioned water circulation component 20 includes the first water inlet and the first water outlet.Above-mentioned water circulation component 20 by first into
The mouth of a river is connected with the first water outlet with visual groove body 30, to realize the cycle of water in visual groove body 30.Water circulation component 20 is also wrapped
It includes and is connect respectively with discharge, waterpipe to, drainage pipeline and circulating pump, the both sides of circulating pump.First water inlet and the first water outlet
Mouth is respectively arranged to, the one end of drainage pipeline far from circulating pump.Optionally, water circulation component 20 includes strainer and electrically-controlled valve
Door, first water inlet and the first water outlet are both provided with strainer and electric control valve, and the strainer is Chong Die with electric control valve to be set
It puts.The electric control valve is used to adjust the flow and flow velocity of the water in visual groove body 30.
The both ends of visual groove body 30 set the second water inlet 34 and the second water outlet 35 respectively.First water inlet and institute
It states the second water outlet 35 to connect, first water outlet is connect with the second water inlet 34.The water in visual groove body 30 is made to be followed in water
There is certain flow velocity, flow direction etc. under the control of ring assemblies 20.Optionally, visual groove body 30 can be glass groove body, the glass
Glass groove body is spliced to form by organic glass, so can river easy to disassemble and the various constructions of assembling simulation.Preferably, it is organic
The thickness of glass is more than 2cm.The visual groove body 30 include intake chamber 31, effluent trough 32 and river major trough 33, described second into
The mouth of a river 34 is located at the intake chamber 31, and second water outlet 35 is located at the effluent trough 32, the intake chamber 31, effluent trough 32
It is respectively arranged at the both sides of the river major trough 33.Further, river major trough 33 includes the first slot section 331 and the second slot section
332.The first slot section 331 is connected with the second slot section 332, and structure between the first slot section 331 and the second slot section 332
Into a preset angle.Junction between first segment and the second slot section 332 is spliced with arc glass plate, with simulating riverway
Corner.Can be with the live body fingerling used in dropping test in visual groove body 30, the river biology that can also have some common is such as
Shrimp, spiral shell, crab and loach etc. simulate an existing biocoene.
The self-loopa river ecological simulation monitoring device 100 further includes inlet damper 50.The inlet damper 50 is set
In in visual groove body 30.Optionally, inlet damper 50 can be set between the intake chamber 31 and the river major trough 33, it is described
Inlet damper 50 can also be set between effluent trough 32 and the river major trough 33.Multiple apertures are set on the inlet damper 50
Apopore for 2cm.Apopore is uniformly arranged on inlet damper 50, plays the role of buffering, energy dissipating, can more realistically simulate day
The streamflow regime in right river.As a kind of possible embodiment, the inlet damper 50 includes telescopic baffle, the flexible gear
Plate is pierced into from the bottom of the visual groove body 30 in the visual groove body 30, the both sides of the telescopic baffle respectively with it is described visual
The side walls connection of groove body 30.The telescopic baffle can be stretched according to the instruction received towards the side far from the bottom
Or it bounces back towards the bottom.To simulate different water environments.
The hydrodynamic force detection components 40 are set between 34 and second water outlet 35 of the second water inlet.The hydrodynamic(al)
Power detection components 40 include triangular-notch weir baffle and needle water level gauge, and the both ends of the river major trough 33 are respectively provided with triangular-notch weir baffle and water
Position stylus.
The self-loopa river ecological simulation monitoring device 100 further includes water-bed ecological artificial layer 60 as shown in Figure 2.Institute
The bottom that water-bed ecological artificial layer 60 is fixed on the visual groove body 30 is stated, the bottom ecological artificial layer 60 includes light and emulates
Device 61, thermostat 62 and water speed modulator 63, the light emulator 61, thermostat 62 and water speed modulator 63 are used
In simulation of the realization to a variety of river states.For example, light emulator 61 is for emulating illumination condition, light emulator 61 can be with
It is submarine light.Thermostat 62 is used to emulate the coolant-temperature gage situation in the river of different zones.Further, water-bed ecological artificial
Layer 60 is laid with the groove shape that the matrix such as substances such as boulder and cobble, silt and water plant in river bed are built into certain length, so that
Water keeps certain mobility.
As shown in figure 3, above-mentioned self-loopa river ecological simulation monitoring device 100 further includes controller 70 and monitoring terminal
80.The controller 70 is electrically connected respectively with the hydrodynamic force detection components 40, water circulation component 20 and monitoring terminal 80, institute
Controller 70 is stated for controlling the working condition of the water circulation component 20, to realize the stream to the water in the visual groove body 30
Amount control, the controller 70 are additionally operable to obtain the stream of the water in the visual groove body 30 by the hydrodynamic force detection components 40
Data are measured, and the data on flows is fed back into the monitoring terminal 80, to show the flow by the monitoring terminal 80
Data, the monitoring terminal 80 is used to send control instruction to the controller 70, to control the work shape of the controller 70
State.It should be noted that the light emulator 61, thermostat 62, water speed modulator 63 and electric control valve also respectively with
The controller 70 connects.The controller 70 is additionally operable to control the light emulator 61, thermostat 62, electric control valve
And the working condition of water speed modulator 63, to realize the simulation to a variety of river states.Relevant staff can pass through monitoring
Terminal 80 sends control instruction to controller 70, to control light emulator 61, thermostat 62 and water speed modulator 63
Working condition reaches the river basic demand that needs are simulated.The working condition of the electric control valve is controlled again, to meet to difference
The control of water speed and flow.
Further, controller 70 is also electrically connected with the telescopic baffle, and the telescopic baffle is in the controller 70
Control under towards far from the bottom side stretching, extension or towards the bottom bounce back.Preferably, the electric control valve also with it is described
Controller 70 is electrically connected, and the controller 70 is used to control the working condition of the electric control valve.
By above-mentioned design, self-loopa river ecological simulation monitoring device 100 at least has advantages below:
(1) device can arbitrarily be laid with riverbed substrate according to the river to be simulated, can carry out any time
Scientific research and testing work, can also annual water quality, water temperature, the flow and flow rate for monitoring riverbed on-line;Continuous long-term on-line monitoring, ensures
The continuity and integrality of experimental data.
(2) device arbitrarily can control river water body water quality parameter according to experimental program setting, have natural practical river
The advantage of water quality Parameters variation is unable to control in road, than the natural river that practical river is more simple, more artificially controls
Model.
(3) the device groove body is all made of the organic glass of 2cm thickness, and anti-corrosion is nontoxic, durable, water pressure resistance.By saturating
Bright organic glass groove body can intuitively monitor the life habit of bioorganism, Burden-Swimming Ability of KM, habitat dynamics and
The behavior response generated under different ecological environmental condition.It also can be according to river actual conditions come illumination simulation intensity, duration, noise
And under the different experimental conditions such as water quality of river, hydrodynamic condition bioorganism behavior response.
(4) simulator uses adjustable water circulation system, can adjust river water body flow velocity as needed, improves
The use scope of the device.
(5) device can also simulate the river with bend according to erecting bed condition simulation into direct current river, whole
It is detachable, easy cleaning, carrying and assembling to cover simulation system.
Second embodiment
It please refers to Fig.4, Fig. 4 shows a kind of self-loopa river ecological simulation monitoring system that the utility model embodiment provides
System 200.The self-loopa river ecological provided the system comprises online water quality monitoring instrument 201 and first embodiment simulates monitoring
Device 100.The online water quality monitoring instrument 201 and the prison in self-loopa river ecological simulation monitoring device 100
It surveys terminal 80 to be electrically connected, the test section of the online water quality monitoring instrument 201 is set in the visual groove body 30, the inspection
Survey portion is used to detect the water quality factor data of the water in the visual groove body 30, and feeds back to the monitoring terminal 80.By monitoring
Terminal 80 shows water quality factor data.In above system operational process, relevant staff can manually launch pollution
Object, then self-loopa river ecological simulation monitoring device 100 is controlled to control the hydrodynamic condition in visual groove body 30, then may be used
It is biological to river with migration, the characteristics of motion, pollution of the data research pollutant of the display according to monitoring terminal 80 in river
Various hydrological characteristics of the influence of group, river purification ability and river etc..
In conclusion a kind of self-loopa river ecological simulation monitoring device and system that the utility model embodiment provides.
The visual groove body of described device is installed on the mounting assembly.The water circulation component includes the first water inlet and the first water outlet
Mouthful, the both ends of the visual groove body set the second water inlet and the second water outlet, first water inlet and described second respectively
Water outlet connects, and first water outlet is connect with the second water inlet, and the controller is electrically connected with water circulation component, described
Controller is used to control the working condition of the water circulation component, to realize the flow control to the water in the visual groove body,
It is simulated so as to fulfill to the streamflow regime in true river, is the research of relationship between biobehavioral and envirment factor variation
It provides convenience.The hydrodynamic force detection components are set between second water inlet and the second water outlet, the controller
It is electrically connected respectively with the hydrodynamic force detection components and the monitoring terminal.The controller is additionally operable to through the hydrodynamic force
Detection components obtain the data on flows of the water in the visual groove body, and the data on flows is fed back to the monitoring terminal,
So that the data on flows is shown by the monitoring terminal.Relative in the relevant technologies in the mode that true river is observed and
Speech, can more accurately change hydrodynamic condition and the aquatic environment factor, to obtain accurately observation or evaluation river ecological ring
The result of the health status in border.It saves and studies time-consuming and manpower and materials.Continuous long-term on-line monitoring can be achieved, ensure experimental data
Continuity and integrality.Have great importance to the research and protection of environment.
It should be noted that herein, relational terms such as first and second and the like are used merely to a reality
Body or operation are distinguished with another entity or operation, are deposited without necessarily requiring or implying between these entities or operation
In any this practical relationship or sequence.Moreover, term " comprising ", "comprising" or its any other variant are intended to
Non-exclusive inclusion, so that process, method, article or equipment including a series of elements not only will including those
Element, but also including other elements that are not explicitly listed or further include as this process, method, article or equipment
Intrinsic element.In the absence of more restrictions, the element limited by sentence "including a ...", it is not excluded that
Also there are other identical elements in process, method, article or equipment including the element.
The above descriptions are merely preferred embodiments of the present invention, is not intended to limit the utility model, for this
For the technical staff in field, various modifications and changes may be made to the present invention.It is all in the spirit and principles of the utility model
Within, any modification, equivalent replacement, improvement and so on should be included within the scope of protection of this utility model.It should be noted that
It arrives:Similar label and letter represents similar terms in following attached drawing, therefore, once determined in a certain Xiang Yi attached drawing
Justice does not need to then that it is further defined and explained in subsequent attached drawing.
Claims (10)
1. a kind of self-loopa river ecological simulates monitoring device, which is characterized in that described device includes mounting assembly, water cycle group
Part, visual groove body, hydrodynamic force detection components, controller and monitoring terminal, the visual groove body are installed on the mounting assembly, institute
State water circulation component and include the first water inlet and the first water outlet, the both ends of the visual groove body set respectively the second water inlet and
Second water outlet, first water inlet are connect with second water outlet, and first water outlet is connect with the second water inlet,
The hydrodynamic force detection components are set between second water inlet and the second water outlet, the controller respectively with the water
Dynamic testing component, water circulation component and monitoring terminal are electrically connected, and the controller is used to control the water circulation component
Working condition, to realize the flow control to the water in the visual groove body, the controller is additionally operable to through the hydrodynamic force
Detection components obtain the data on flows of the water in the visual groove body, and the data on flows is fed back to the monitoring terminal,
So that the monitoring terminal shows the data on flows, the monitoring terminal is used to send control instruction to the controller, with
Control the working condition of the controller.
2. device as described in claim 1, which is characterized in that described device further includes inlet damper, the visual groove body packet
Intake chamber, effluent trough and river major trough are included, second water inlet is located at the intake chamber, and second water outlet is located at described
Effluent trough, the intake chamber, effluent trough are respectively arranged at the both sides of the river major trough, the intake chamber and the river major trough
Between inlet damper is set, inlet damper is set between the effluent trough and the river major trough.
3. device as claimed in claim 2, which is characterized in that the river major trough includes the first slot section and the second slot section, institute
It states the first slot section to connect with the second slot section, and a preset angle is formed between the first slot section and the second slot section.
4. device as claimed in claim 2, which is characterized in that multiple apopores are set on the inlet damper.
5. device as claimed in claim 2, which is characterized in that the inlet damper includes telescopic baffle, the telescopic baffle
Pierced into the visual groove body from the bottom of the visual groove body, the both sides of the telescopic baffle respectively with the visual groove body
Side walls connect, and the telescopic baffle is electrically connected with the controller, and the telescopic baffle is used for according in the control
It bounces back under the control of device towards the side stretching, extension far from the bottom or towards the bottom.
6. device as claimed in claim 2, which is characterized in that the hydrodynamic force detection components include triangular-notch weir baffle and water level
Stylus, the both ends of the river major trough are respectively provided with triangular-notch weir baffle and needle water level gauge.
7. device as described in claim 1, which is characterized in that the water circulation component includes strainer and electric control valve, described
First water inlet and the first water outlet are both provided with strainer and electric control valve, and the strainer is overlapped with electric control valve, described
Electric control valve is electrically connected with the controller, and the controller is used to control the working condition of the electric control valve.
8. such as claim 1-7 any one of them devices, which is characterized in that the visual groove body includes glass groove body, described
Glass groove body is spliced to form by organic glass.
9. device as claimed in claim 8, which is characterized in that described device further includes water-bed ecological artificial layer, the bottom
Ecological artificial layer is fixed on the bottom of the visual groove body, and the bottom ecological artificial layer includes light emulator, lower water temperature
Device and water speed modulator, the light emulator, thermostat and water speed modulator are connect respectively with the controller, described
Controller is additionally operable to control the working condition of the light emulator, thermostat and water speed modulator, to realize to a variety of
The simulation of river state.
10. a kind of self-loopa river ecological simulates monitoring system, which is characterized in that the system comprises online water quality monitoring instruments
And as claim 1-9 any one of them self-loopas river ecological simulate monitoring device, the online water quality monitoring instrument with
The monitoring terminal in the self-loopa river ecological simulation monitoring device is electrically connected, the online water quality monitoring instrument
Test section is set in the visual groove body, and the test section is used to detect the water quality factor number of the water in the visual groove body
According to, and feed back to the monitoring terminal.
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