TWM518800U - Fish culture ecological monitoring device - Google Patents

Description

Aquaculture ecological monitoring device

This creation is about an aquaculture ecological monitoring device, in particular a collection and transfer of water quality information from water quality sensors to a database for storage, as well as providing corresponding controls or alarms to monitor water quality information and control water tankers (aerators) ) and the aquaculture ecological monitoring device that feeds the system switch to achieve long-term water quality monitoring and saves water and electricity.

The underwater sensor probe of the surimi becomes dirty due to the easy attachment of algae, microorganisms, eggs, and sticky objects, which in turn causes the sensor to measure the correct value due to numerical attenuation, which is optically dissolved. Oxygen sensors are most likely to fail due to dirt.

Therefore, how to design a water quality information measurement and transmission to the database storage, and provide corresponding control or alarm to monitor water quality information, and control the water tank (aerator) and feeding system switch to achieve long-term The aquaculture ecological monitoring device, which monitors water quality and saves water and electricity, has become the goal of related manufacturers and related R&D personnel.

The creators of this case have not been able to meet the water quality information collected and transmitted to the database for water quality sensor measurement, and provide corresponding control or alarm to monitor water quality information and control the waterwheel (aerator) switch. Long-term water quality monitoring, and the lack of water and electricity saving needs, is actively developing, in order to improve the above-mentioned shortcomings, and through continuous experimentation and efforts, finally developed this creation.

The purpose of this creation is to provide an aquaculture ecological monitoring device that collects and transmits water quality information measured by water quality sensors to a database for storage and provides corresponding control or alarm.

In order to achieve the above objectives, the aquaculture ecological monitoring device of the present invention comprises a wireless internet of things, a concentrator, a water quality monitoring subsystem, a water tanker (aerator) alarm control subsystem and a feed monitoring subsystem.

The wireless Internet of things includes at least one access point wireless module and at least two wireless modules. The wireless modules are respectively connected to the access point wireless module by a path and registered, and the measured data is transmitted. Give the access point a wireless module.

The concentrator is coupled to the access point wireless module and collects data of the wireless modules, transmits the data to a back-end database through a wireless communication unit, and receives a central control center through the wireless communication unit The command is then transferred to the corresponding wireless module through the access point wireless module, and the back-end database can be set as a local database, and the local database can send the data to the Internet through the Internet. Cloud database to store and organize collected water quality data.

The water quality monitoring subsystem is connected to one of the wireless modules, a water quality monitoring input and output module and a measuring device, and the water quality monitoring input and output module is connected with a water tanker (aerator) and a feed monitoring device. The subsystem is connected and connected with the water motor (aerator) and the control motor of the feeding monitoring subsystem and the water discharge switch, and the measuring device takes water sampling and measures the water quality data.

The water tanker (aerator) alarm control subsystem is connected to one of the wireless modules, and includes a water tanker (aerator) alarm input and output module and a display device, one of the wireless modules The storage configuration data, the water tanker (aerator) alarm input and output module is connected with at least one water tanker (aerator) and the feed monitoring subsystem and an alarm device, when the water quality of the water tanker (aerator) When the data is changed, the water heater (aerator), the feeding monitoring subsystem, and the alarm are controlled to issue an alarm according to the setting switch, and the display device displays the water tank (aerator) and the feeding monitoring subsystem. Water quality data and the control status of such water tankers (aerators) and the feed monitoring subsystem.

Through the above structure, the creation collects and transmits the water quality information measured by the water quality sensor to the database for storage, and provides corresponding control or alarm to monitor the water quality information and control the waterwheel (aerator) and the feed monitoring subsystem switch. To achieve long-term water quality monitoring and save water and electricity.

In order to familiarize the person skilled in the art with the purpose of the present invention, the preferred embodiment of the present invention will be described in detail below with reference to the drawings.

Please refer to Figure 1, the aquaculture ecological monitoring device (1) of this creation includes a wireless Internet of Things (10), a concentrator (11), a water quality monitoring subsystem (12), and a water tank (oxygenation). The alarm control subsystem (13) and a feed monitoring subsystem (14).

The wireless Internet of Things (10) includes at least one access point wireless module (100) and at least two wireless modules (101), wherein the wireless modules (101) are respectively connected to the access point wireless module by a path. The group (100) registers and transmits the measured data to the access point wireless module (100).

The concentrator (11) is coupled to the access point wireless module (100), and collects data of the wireless modules (101), and transmits the data to a back-end database through a wireless communication unit (110). (not shown), and receiving a command from a central control center (not shown) through the wireless communication unit (110), and then transmitting the wireless module (100) through the access point to the corresponding wireless module (101) The back-end database can be set as a local database, and the local database can send the data to a cloud database (not shown) through the Internet to store and organize the collected water quality data.

The water quality monitoring subsystem (12) is connected to one of the wireless modules (101), a water quality monitoring input and output module (120), and a measuring device (121), and the water quality monitoring input and output module ( 120) is connected with a water tanker (aerator) (2), and is connected to the water motor (aerator) and the control motor of the feeding monitoring subsystem and the water discharge switch (20), and the measuring device (121) is taken from the water. Sampling and measuring water quality data.

The waterwheel (aerator) alarm control subsystem (13) is connected to one of the wireless modules (101) and includes a water tanker (aerator) alarm input and output module (130) and a display The device (131), one of the wireless modules (101) stores configuration data, and the water tanker (aerator) alarm input and output module (130) is coupled to at least one water tanker (aerator) (2) The feeding monitoring subsystem (140) and an alarm device (not shown) are connected, and when the water quality data of the water tanker (aerator) (2) and the feeding monitoring subsystem (140) are changed, the setting switch is The water tanker (aerator) (2) and the feed monitoring subsystem (140) control the alarm to issue an alarm, and the display device (131) displays the water tanker (aerator) (2) and the feed The water quality data of the monitoring subsystem (140) and the control status of the water tanker (aerator) (2) and the feed monitoring subsystem (140).

In a preferred embodiment of the present invention, the feed monitoring subsystem (140) is coupled to a plurality of feeders (3).

In a preferred embodiment of the present invention, the wireless communication unit (110) utilizes mobile communication technologies (2G, GPRS, 3G, 4G, and 5G and above), wireless local area network (WiFi), or Ethernet. The Internet (Ethernet) passes the data to the backend database.

In another preferred embodiment of the present invention, the wireless Internet of Things (10) uses a Water-fall mesh protocol, a Spanning Tree protocol, or a Star Protocol ( Star protocol).

In another preferred embodiment of the present invention, the water quality monitoring subsystem (12) measures the dissolved oxygen, water temperature, turbidity, nitrate nitrogen, and conductance of the water through the measuring device (121). Degree, ammonia nitrogen, salinity, pH, redox potential, total dissolved solids, residual chlorine data.

In still another preferred embodiment of the present invention, the user monitors the water quality data of each place through the cloud database, and returns the relevant personnel when the water quality is abnormal.

In addition, the creation can also receive remote users to change the settings of a station or remotely control the switches of the water tanker (aerator) and the feed monitoring subsystem through the mobile application or the network command, and Meteorological data from all regions, together with the water quality data of the cloud database, analyze the data and generate relevant reports.

Through the above structure, the author collects and transmits the water quality information measured by the water quality sensor to the database for storage, and provides corresponding control or alarm to monitor the water quality information and control the waterwheel (aerator) switch to achieve long-term water quality. Monitor and save water and electricity. Moreover, its structural form is not easily reached by those skilled in the art, and it is novel and progressive.

Through the above detailed description, it can fully demonstrate that the purpose and effect of this creation are both progressive and extremely industrially valuable, and it is a new creation that has never been seen before in the market, and fully conforms to the new patent requirements. , 提出 apply in accordance with the law. The above description is only for the preferred embodiment of the present invention, and cannot be used to limit the scope of the present invention. That is, all the changes and modifications made in accordance with the scope of this patent should belong to the scope of this new patent. I would like to ask your review committee to give a clear understanding and pray for it.

(1) ‧ ‧ aquaculture ecological monitoring device
(10) ‧‧‧Wireless Internet of Things
(100)‧‧‧Access Point Wireless Module
(101)‧‧‧Wireless Module
(11)‧‧‧ Concentrator
(110)‧‧‧Wireless communication unit
(12) ‧‧‧Water quality monitoring subsystem
(120)‧‧‧Water quality monitoring input and output module
(121)‧‧‧Measurement device
(13)‧‧‧Waterwheel (aerator) alarm control subsystem
(130)‧‧‧Waterwheel (aerator) alarm input and output module
(131)‧‧‧Display devices
(140)‧‧‧Feed monitoring subsystem
(2)‧‧‧Waterwheel (aerator)
(20) ‧‧‧Waterwheel (aerator) and control motor for the monitoring subsystem and drain switch
(3)‧‧‧ Feeder

Figure 1 is a schematic diagram of the system of the aquaculture ecological monitoring device of the present invention.

(1) ‧ ‧ aquaculture ecological monitoring device

(100)‧‧‧Access Point Wireless Module

(101)‧‧‧Wireless Module

(11)‧‧‧ Concentrator

(110)‧‧‧Wireless communication unit

(12) ‧‧‧Water quality monitoring subsystem

(120)‧‧‧Water quality monitoring input and output module

(121)‧‧‧Measurement device

(13)‧‧‧Waterwheel (aerator) alarm control subsystem

(130)‧‧‧Waterwheel (aerator) alarm input and output module

(131)‧‧‧Display devices

(140)‧‧‧Feed monitoring subsystem

(2)‧‧‧Waterwheel (aerator)

(20) ‧‧‧Waterwheel (aerator) and control motor for the monitoring subsystem and drain switch

(3)‧‧‧ Feeder

Claims (5)

An aquaculture ecological monitoring device includes: a wireless Internet of things, comprising at least one access point wireless module and at least two wireless modules, wherein the wireless modules are respectively connected to the access point wireless module by a path And registering the measured data to the access point wireless module; a concentrator is coupled to the access point wireless module and collects data of the wireless modules through a wireless communication unit Passing the data to a back-end database, and receiving a command from the central control center through the wireless communication unit, and transmitting the wireless module to the corresponding wireless module through the access point, the back-end database can be set to In the local database, the local database can send data to a cloud database through the Internet to store and organize the collected water quality data; a water quality monitoring subsystem is associated with the wireless modules 1. A water quality monitoring input/output module and a measuring device connection, the water quality monitoring input and output module is connected with a water tanker (aerator) and a feeding monitoring subsystem, and the water tanker (aerator) and a control motor of the feed monitoring subsystem and a drain switch connection, the measuring device is configured to take water sampling and measure water quality data; and a water tanker (aerator) alarm control subsystem is connected to one of the wireless modules, and The utility model comprises a water tanker (aerator) alarm input and output module and a display device, wherein one of the wireless modules stores configuration data, and the water tanker (aerator) alarm input and output module is connected with at least one waterwheel ( The aerator (the aerator), the feed monitoring subsystem and an alarm device are connected, and when the water quality data of the water tanker (aerator) and the feed monitoring subsystem are changed, the water truck (aerator) and the Feeding the monitoring subsystem and controlling the alarm to issue an alarm, the display device displaying water quality data of the water tanker (aerator) and the feeding monitoring subsystem, and the water tanker (aerator) and the feeding monitoring subsystem Control the situation. For example, the aquaculture ecological monitoring device described in claim 1 wherein the wireless communication unit utilizes mobile communication technologies (2G, GPRS, 3G, and 4G), wireless local area network (WiFi), or Ethernet (Ethernet). Transfer the data to the backend repository. The aquaculture ecological monitoring device according to claim 1 or 2, wherein the wireless Internet of Things uses a Water-fall mesh protocol, a Spanning Tree protocol, or a star. Protocol (Star protocol). The aquaculture ecological monitoring device according to claim 1 or 2, wherein the water quality monitoring subsystem measures the dissolved oxygen, water temperature, turbidity, nitrate nitrogen and conductance of the water through the sampling device. Degree, ammonia nitrogen, salinity, pH, redox potential, total dissolved solids, residual chlorine data. The aquaculture ecological monitoring device according to claim 3, wherein the water quality monitoring subsystem measures water dissolved oxygen, water temperature, turbidity, nitrate nitrogen, electrical conductivity, and water quality through the measuring device. Ammonia nitrogen, salinity, pH, redox potential, total dissolved solids, residual chlorine data.