TWI483676B - Aquaculture system - Google Patents

Description

Aquaculture system

The present invention relates to an aquaculture system, and more particularly to an aquaculture system for monitoring the operational status of an aquaculture farm.

Natural catches are rich and diversified into the world's major economic resources. However, in recent years, due to global overfishing, trawling vessels, and improper fishing methods such as electric fish, poisonous fish, and spur nets, the catch has been reduced and fish species have gradually declined. Depletion, relatively highlights the importance of aquaculture. Aquaculture has always been one of Taiwan's important economic industries. The rapid development of aquaculture in the past 20 years has brought abundant income to China. In addition to shrimps, aquaculture organisms also contain a variety of aquaculture fish species such as groupers, carp, milkfish and sea otters.

The aquaculture system is a large-scale, high-density farming system. It is not possible to carry out various farming operations one by one. Therefore, traditional aquaculture farms must have equipment such as water pumps, pumping motors and drainage systems. However, the operation of each equipment is still It is necessary to rely on the aquaculture industry to dispatch manpower to actively control, for example, based on the number of farmed fry, estimate the timing of the water pump, determine the water change timing according to the self-measured pH and water temperature, or judge whether the water needs to be increased according to the visual water level. Or drainage action, etc.

However, it is difficult for manpower to monitor the condition of the farm 24 hours a day, and it is often easy to miss the timing of starting the relevant equipment, resulting in the occurrence of fry damage. Moreover, once the number of farms in the industry is expanded and the farms have a certain distance from each other, the need to monitor the ponds separately will result in a manager. There is a lack of skill, and a slight loss may cause a sudden drop in production, which is an unbearable loss for the breeder.

In addition, due to the lack of proper power monitoring facilities to confirm the operation of various equipment in the aquaculture farm, once the equipment fails, the manager does not immediately find out that it is very likely to cause a lot of violent fry when the equipment is properly started. Or the equipment is not properly shut down, resulting in a large amount of wasted power or water resources, which in vain increases the operating costs of the operators.

In summary, the aquaculture farms have many shortcomings such as “inefficient”, “energy consuming” and “low safety” for the management of various equipment. Therefore, it is necessary to provide a further improved aquaculture system to Promote the development of Taiwan's aquaculture industry.

The object of the present invention is to improve the above-mentioned disadvantages to provide an aquaculture system by which a plurality of aquaculture farms can be simultaneously monitored and the operation of the aquaculture farms can be inquired whenever and wherever possible. Efficiency, to achieve the effect of increasing aquaculture production.

Another object of the present invention is to provide an aquaculture system which ensures normal operation of equipment in an aquaculture farm through electric power monitoring equipment, can avoid abnormal opening or closing of equipment, has energy saving and carbon reduction, and saves farming cost. efficacy.

Another object of the present invention is to provide an aquaculture system which, when an abnormal state is found, immediately informs the aquarist to perform the treatment, and has the effect of improving the safety of the system.

The aquaculture system of the present invention comprises: at least one breeding equipment for The action required to perform the aquaculture operation; a power monitoring module coupled to the breeding equipment to sense the power information of the breeding equipment, the power monitoring module has an information output terminal for outputting power information of the breeding equipment And a network monitoring unit having a data collection end and a user transceiver end, the data collection end coupled to the information output end of the power monitoring module for receiving power information of the breeding equipment, and calculating the breeding equipment The power consumption state, and determining whether the operation state of the breeding equipment is normal, the user transceiver end is provided for the user to log in to the network monitoring unit through a network communication manner to read the operating state of the breeding equipment; An environmental parameter monitoring module for sensing environmental conditions of the aquaculture farm, the environmental parameter monitoring module having an information output end for coupling to the data collecting end for outputting the sensed environmental condition information to the The network monitoring unit is configured for the user to log in; wherein the environmental parameter monitoring module includes a fish length detector and a water level detection The fish length detector is for measuring and calculating the length data of the aquatic organisms cultured in the aquaculture site, and judging whether the difference in the length of the aquatic organisms cultured in the aquaculture site reaches the pooling operation standard, The water level height detector is configured to detect the water level height information of the aquaculture farm, and determine whether the water level height is abnormal, and the breeding equipment comprises a pumping motor and a drainage system, and the water level detector determines the water level When the altitude is abnormal, the pumping motor or the drainage system is controlled to adjust the water level of the aquaculture system.

The aquaculture system of the present invention further comprises a water quality parameter monitoring module for sensing the water quality parameter of the aquaculture farm, the water quality parameter monitoring module has an information output end for coupling to the data collecting end, Outputting the sensed water quality parameter information to the network monitoring unit for use Login to read.

The aquaculture system of the present invention, wherein the water quality parameter monitoring module comprises at least one water quality sensor for detecting water quality parameter information of the aquaculture farm, and determining whether the water quality parameter is abnormal, and the breeding equipment The utility model comprises a pumping motor and a drainage system. When the water quality sensor determines that the water quality parameter is abnormal, the water pump and the drainage system are controlled to perform a water exchange operation on the aquaculture farm.

The aquaculture system of the present invention, wherein the water quality sensor comprises a dissolved oxygen rate sensor for detecting the dissolved oxygen amount of the aquaculture farm, and determining whether it is too low, and the breeding equipment further comprises a The water pump controls the water pump to perform an aeration operation on the aquaculture farm when the dissolved oxygen rate sensor determines that the dissolved oxygen ratio is too low.

The aquaculture system of the present invention, wherein the electricity state of the culture equipment comprises a voltage value and a current value, and the network monitoring unit determines whether the operation state of the culture equipment is based on the voltage value, the current value and the switching state of the breeding equipment. Normally, when the network monitoring unit determines that the operating state of the breeding equipment is abnormal, a warning message is sent through the user transceiver.

The above and other objects, features, and advantages of the present invention will become more apparent from the claims. The system architecture diagram of the first embodiment of the aquaculture system of the present invention, the aquaculture system is disposed in an aquaculture farm P, comprising at least one breeding equipment 1, a power monitoring module 2 and a net Road monitoring unit 3. The power monitoring module 2 is coupled to the power monitoring module 2, and the power monitoring module 2 is coupled to the network monitoring unit 3.

The breeding apparatus 1 is for performing the operations required for aquaculture. In the present embodiment, the breeding apparatus 1 comprises a drainage system 11, a pumping motor 12 and a water pump 13, and preferably further comprises a feeding machine 14 However, the invention is not limited thereto. Wherein, when the drainage system 11 is started, the aquaculture farm P may be drained; when the pumping motor 12 is started, the aquaculture farm P may be subjected to a water increasing action; when the water pump 13 is started, the water pump 13 may be activated. The aquaculture farm P performs an aeration operation; when the feeding machine 14 is started, the aquaculture farm P can be fed with bait.

The power monitoring module 2 is composed of a conventional power sensing device, and is coupled to each of the farming equipment 1 such as the drainage system 11, the pumping motor 12, the water pump 13, and the feeding machine 14, to sense each of the breeding devices. Power information such as voltage and current of device 1. The power monitoring module 2 has an information output terminal 21 through which the sensed power information can be output.

The network monitoring unit 3 is composed of a computing device such as a workstation host, a personal computer or a mobile computing device, and includes a data collecting end 31 coupled to the information output end 21 of the power monitoring module 2, Receiving power information sensed by the power monitoring module 2. The network monitoring unit 3 calculates the voltage value consumed by each of the farming equipment 1 such as the drainage system 11, the pumping motor 12, the water pump 13, and the feeding machine 14 according to the power information sensed by the power monitoring module 2, A power state such as a current value or a power is used to determine the operational state of each of the breeding equipment 1.

The network monitoring unit 3 further includes a user transceiver 32 for the user to access at least one conventional communication device such as a personal computer, a notebook computer, and a smart device. A type of mobile phone or a personal data processor (PDA), etc., coupled by a conventional network communication method. In the present embodiment, the conventional network communication method preferably uses wired or wireless network transmission technologies such as RS485, Ethernet, 802.11, GPRS, 3G, 4G or WiFi. Thereby, the user can know that the communication device logs into the network monitoring unit 3 through a wired or wireless network transmission technology to read the operating status of each device. In addition, when the network monitoring unit 3 detects that the power state of any of the breeding equipment 1 is abnormal, for example, the voltage value or the current value is too high, or one of the voltage value or the current value is abnormally zero, etc., The breeding device 1 may have a fault condition such as a short circuit or an open circuit, that is, a warning message is sent to the user through the user transceiver 32, and the warning message may be a voice, a logo, a light number, a newsletter or an email, etc., and the user is viewed. The type of the conventional communication device to which the transceiver terminal 32 is coupled depends.

Please refer to FIG. 2, which is a control flow chart of the first embodiment of the aquaculture system of the present invention. Since the drainage system 11, the water pumping motor 12, the water pump 13 and the feeding machine 14 are coupled to the power monitoring module 2, the power monitoring module 2 can continuously perform power monitoring operations. The power information such as voltage and current of each of the breeding equipment 1 is sensed, and the sensed power information is output to the data collecting end 31 of the network monitoring unit 3 through the information output terminal 21. The network monitoring unit 3 calculates information such as a voltage value, a current value, or a power consumption of each of the breeding equipment 1 based on the power information to determine the operating status of each of the breeding equipment 1 and for the user to transmit through the user transceiver 32. Log in and read to master the real-time operation of each breeding equipment 1 and complete the network monitoring operation. In addition, when the network monitoring unit 3 detects that the power state of any of the breeding equipment 1 is abnormal, That is, the user transceiver 32 attempts to send a warning message to the user to remind the user of the operation of the breeding device 1.

By setting up the aquaculture system of the present invention in a plurality of aquaculture farms P, the user can log in to the network monitoring unit 3 of each aquaculture system by the user transceiver 32 by using a conventional communication device such as a computer or a mobile phone. It is possible to monitor the operation of the breeding equipment 1 in each of the aquaculture farms P, which has the effect of improving management efficiency.

Furthermore, the network monitoring unit 3 can fully display the operation status of the aquaculture farm P, and the user can actually perform power monitoring on the breeding equipment 1. Once the breeding equipment 1 is closed, it is not closed or should be started but not started. The situation occurs, it is easier to be discovered and timely repaired. Compared with the traditional, it depends on visually confirming the operation status of the breeding equipment 1 and increasing the labor cost or the risk of human error, which has the effect of saving the breeding cost.

In addition, when the network monitoring unit 3 detects that the power consumption status of any of the breeding equipment 1 is abnormal, a warning message is sent to the user through the user transceiver terminal 32 to notify the user that the breeding equipment 1 may occur. In the case of a fault, the user can immediately perform the relevant maintenance after receiving the warning message. In the past, it is necessary to rely on the manpower to find out that the breeding equipment 1 is faulty, and the situation may have occurred due to the burning of the equipment or the death of the fry. Accordingly, the invented aquaculture system has the effect of greatly improving safety.

Please refer to FIG. 3 , which is a system architecture diagram of a second embodiment of the aquaculture system of the present invention. The difference from the first embodiment is that the aquaculture system further includes an environmental parameter monitoring module 4 and a water quality parameter monitoring module 5, the environmental parameter monitoring module 4 and the water quality parameter monitoring module 5 are also disposed in the aquaculture farm P, and respectively connected to the network monitoring unit 3, And can operate independently. Further, in the present embodiment, the drainage system 11, the pumping motor 12, and the water pump 13 are respectively provided with a controlled end 111, 121, 131.

The environmental parameter monitoring module 4 is configured to monitor the environmental conditions of the aquaculture farm P, including a fish length detector 41 and a water level height detector 42, but the invention is not limited thereto. The fish length detector 41 is capable of measuring and calculating the length data of the aquatic organisms such as the fry or the shrimps in the aquaculture farm P, and judging the length of the aquatic organisms cultured in the aquaculture farm P Whether the degree of difference reaches the standard of the pooling operation. The water level detector 42 is capable of detecting the water level of the aquaculture farm P and determining whether the water body of the aquaculture farm P meets the low water level or the full water level. The fish length detector 41 and the water level detector 42 can be constructed using the "water biological detection device" of the Patent Application No. 101146679. The environmental parameter monitoring module 4 is coupled to the drainage system 11 and the controlled ends 111 and 121 of the pumping motor 12, and the environmental parameter monitoring module 4 further includes an information output terminal 43 through which the information output end can be transmitted. 43 Output the water body information and water level information generated.

The data collection end 31 of the network monitoring unit 3 is coupled to the information output end 43 of the environmental parameter monitoring module 4 for receiving information generated by the environmental parameter monitoring module 4. The fish length detector 41 counts the length data of the aquatic organisms cultured by the aquaculture farm P, and judges whether the pooling operation standard is reached, and outputs the result to the network monitoring unit 3 through the information output terminal 43. The data collecting end 31 is for the user to log in and read through the user transceiver 32; the water level detector 42 detects the water level of the aquaculture farm P, and determines whether the low water level or the full water level is reached. Will result The information output terminal 43 outputs the information to the data collection terminal 31 of the network monitoring unit 3 for the user to log in and read via the user transceiver 32. In addition, when the water level detector 42 determines that the water body of the aquaculture farm P reaches the low water level or the full water level, the determination result is output to the network monitoring unit 3 through the information output terminal 43 to remind the user. In addition, the environmental parameter monitoring module 4 is also coupled to the drainage system 11 and the controlled ends 111 and 121 of the pumping motor 12, so that the environmental parameter monitoring module 4 can also actively operate the breeding equipment. 1 to adjust the water level of the aquaculture farm P.

More specifically, when the water level detector 42 determines that the water level of the aquaculture farm P is too low, the environmental parameter monitoring module 4 activates the pumping motor 12 to perform a water-increasing action on the aquaculture farm P. The pumping motor 12 is turned off until the water level is too low. At the same time, the information of the pumping motor 12 is returned to the network monitoring unit 3 by the information output terminal 43. The network monitoring unit 3 further determines whether the pumping motor 12 has been determined according to the power information sensed by the power monitoring module 2. Normally starting or shutting down, if the pumping motor 12 is not normally started or turned off, the network monitoring unit 3 is notified to send a warning message to the user through the user transceiver 32; conversely, when the water level detector 42 When it is determined that the water level of the aquaculture farm P is full, the environmental parameter monitoring module 4 activates the drainage system 11 to perform drainage operation on the aquaculture farm P until the water level overflows, and then closes the drainage system 11 . At the same time, the information of the drainage system 11 is returned to the network monitoring unit 3 by the information output terminal 43. The network monitoring unit 3 further determines whether the drainage system 11 has been determined according to the power information sensed by the power monitoring module 2. Normally start or shut down, if the drainage system 11 If the network monitoring unit 3 does not normally start or shut down, the network monitoring unit 3 is notified to send a warning message to the user through the user transceiver 32.

The water quality parameter monitoring module 5 is configured to monitor the water quality of the water body of the aquaculture farm P, and includes a water temperature sensor 51, a pH sensor 52, a conductivity sensor 53 and a dissolved oxygen rate. Sensor 54, but the invention is not limited thereto. The water temperature sensor 51, the pH sensor 52, the conductivity sensor 53 and the dissolved oxygen sensor 54 are all conventional water measuring devices, which are understood by those of ordinary skill in the art. The water temperature sensor 51 is capable of measuring the water temperature of the water body of the aquaculture farm P, and determines whether the water temperature is too high or too low. The pH sensor 52 is capable of measuring the pH value of the water body of the aquaculture farm P, and determining whether the pH value is too high or too low. The conductivity sensor 53 is capable of measuring the conductivity of the body of the aquaculture farm P and determining whether the conductivity is too high or too low. The dissolved oxygen rate sensor 54 is capable of measuring the dissolved oxygen rate of the water body of the aquaculture farm P, and determines whether the dissolved oxygen ratio is too high or too low. The water quality parameter monitoring module 5 is coupled to the controlled ends 111, 121, and 131 of the water pumping system 11, the water pumping motor 12, and the water pumping unit 13, and the water quality parameter monitoring module 5 further includes an information output terminal 51. Water quality parameter information such as water temperature, pH value, conductivity, and dissolved oxygen rate generated can be output through the information output terminal 51.

The data collection end 31 of the network monitoring unit 3 is coupled to the information output 51 of the water quality parameter monitoring module 5 for receiving information generated by the water quality parameter monitoring module 5. The water temperature sensor 51 measures the water temperature of the water body of the aquaculture farm P, and determines whether there is a water temperature abnormality, and outputs the result to the network monitoring unit 3 through the information output terminal 51. The collecting end 31 is configured for the user to log in and read through the user transceiver end 32; the sense of pH value The measuring device 52 measures the pH value of the water body of the aquaculture farm P, and determines whether there is an abnormal pH value, and outputs the result to the data collecting end of the network monitoring unit 3 through the information output terminal 51. 31, for the user to log in and read through the user transceiver 32; the conductivity sensor 53 measures the conductivity of the water body of the aquaculture farm P, and according to whether the conductivity is abnormal, the result is transmitted The information output end 51 is output to the data collection end 31 of the network monitoring unit 3 for the user to log in and read through the user transceiver 32; the dissolved oxygen rate sensor 54 measures the water body of the aquaculture farm P. The dissolved oxygen rate is used to determine whether the dissolved oxygen ratio is too low. The result is output to the data collecting end 31 of the network monitoring unit 3 through the information output terminal 51 for the user to log in via the user transceiver 32. Read.

In addition, when the water quality parameter such as the water temperature, the pH value, the conductivity, and the dissolved oxygen ratio is determined to be abnormal, the water quality parameter monitoring module 5 outputs the determination result to the network monitoring unit through the information output terminal 51. 3, in order to remind the user to perform related processing, since the water quality parameter monitoring module 5 is coupled to the controlled ends 111, 121, 131 of the drainage system 11, the pumping motor 12 and the water pump 13, respectively, the water quality parameter The monitoring module 5 can also actively operate the breeding equipment 1 to adjust the water quality of the aquaculture farm P.

More specifically, when the water body of the aquaculture farm P has a water temperature that is too high or too low, the pH is too high or too low, or the conductivity is too high or too low, the water temperature sensor 51 The water-base sensor 52 or the conductivity sensor 53 determines that the water quality parameter of the water body is abnormal. The water quality parameter monitoring module 5 activates the drainage system 11 and the pumping motor 12 to perform the aquaculture farm P. Water change operation, that is, simultaneous water increase or drainage operation to adjust the water quality until the water temperature, pH value and conductivity return to normal values, and then the drainage system The system 11 and the pumping motor 12 are closed. At the same time, the information of the drainage system 11 and the pumping motor 12 is transmitted back to the network monitoring unit 3, and the network monitoring unit 3 further determines the drainage according to the power information sensed by the power monitoring module 2. Whether the system 11 and the pumping motor 12 have been normally started or turned off, if the draining system 11 or the pumping motor 12 is not normally activated or turned off, the network monitoring unit 3 is notified to send a user to the user through the user transceiver 32. In addition, when the dissolved oxygen rate sensor 54 determines that the dissolved oxygen rate of the water in the aquaculture farm P is too low, the water quality parameter monitoring module 5 activates the water pump 13 to perform the aquaculture farm P. The aeration operation is performed until the dissolved oxygen ratio is too low, and the water pump 13 is closed. At the same time, the information of the water pump 13 is returned to the network monitoring unit 3 by the information output terminal 51. The network monitoring unit 3 further determines the water pump 13 according to the power information sensed by the power monitoring module 2. If the water pump 13 is not normally started or turned off, the network monitoring unit 3 is notified to send a warning message to the user through the user transceiver 32.

Please refer to FIG. 4, which is a control flow chart of the second embodiment of the aquaculture system of the present invention. In this embodiment, the feeding machine 14 can be provided with a timer, and the timer is used to set a feeding time. The timer will automatically start the feeding machine 14 for feeding operations every time the feeding time is reached. Through the environmental parameter monitoring module 4, the aquaculture system of the present invention can perform environmental parameter monitoring operations, and calculate the water body length data of the aquaculture farm P, thereby judging whether the difference in body length of the aquatic organism reaches the pooling operation standard; The water level of the aquaculture farm P is also detected to determine whether the low water level or the full water level is reached. Data collection of the network monitoring unit 3 The terminal 31 receives the above information to remind the user whether there is a need for the pool, the water level is too low, or the water level is full. In addition, once the water level detector 42 determines that the water level is too low or the water level is full, the environmental parameter monitoring module 4 will actively operate the breeding equipment 1 to adjust the water level of the aquaculture farm P, and return The information of the breeding device 1 is transmitted to the network monitoring unit 3. The network monitoring unit 3 further determines whether the breeding device 1 is operating normally according to the power information sensed by the power monitoring module 2.

Through the water quality parameter monitoring module 5, the aquaculture system of the present invention can perform water quality parameter monitoring operations, and measure water quality parameter information such as water temperature, pH value, electrical conductivity and dissolved oxygen rate of the aquaculture farm P, according to which Whether the water quality parameter is abnormal. The data collecting end 31 of the network monitoring unit 3 receives the above information to remind the user whether there is a situation in which the water temperature is abnormal, the pH value is abnormal, the conductivity is abnormal, or the dissolved oxygen rate is too low. In addition, once the water quality parameter is abnormal, the water quality parameter monitoring module will actively operate the breeding equipment 1 to adjust the water quality of the aquaculture farm P, and at the same time return the information of the breeding equipment 1 to the network. The network monitoring unit 3 further determines whether the breeding device 1 is operating normally according to the power information sensed by the power monitoring module 2.

The power monitoring module 2 can continuously perform power monitoring operations, sense power information such as voltage and current of each of the breeding equipment 1, and output the sensed power information to the network monitoring unit 3 through the information output terminal 21. Data collection end 31. The network monitoring unit 3 calculates the power state, the current value or the power consumption state of each of the breeding equipment 1 according to the power information, and the 5 environmental parameter monitoring module 4 and the water quality parameter monitoring module 5 are returned. Passing the control message of the breeding equipment 1 to determine whether the breeding equipment 1 is in normal operation, and for the user to log in and read through the user transceiver 32 to grasp the real-time operation of each breeding equipment 1 and complete the network. Monitor the job. In addition, when the network monitoring unit 3 determines that the power consumption status of any of the breeding equipment 1 is abnormal, the user transceiver terminal 32 immediately attempts to send a warning message to the user to remind the user to pay attention to the operation of the breeding equipment 1. situation.

By setting up the aquaculture system of the present invention in a plurality of aquaculture farms P, the user can log in to the network monitoring unit 3 of each aquaculture system by the user transceiver 32 by using a conventional communication device such as a computer or a mobile phone. The water monitoring, environmental parameter monitoring and water quality parameter monitoring operations of each aquaculture farm P can be performed. In addition, the environmental parameter monitoring module 4 and the water quality parameter monitoring module 5 can actively control the breeding equipment 1 to adjust the water level and the water quality parameters of the aquaculture farm P, thereby improving the management efficiency and further increasing the aquaculture production. efficacy.

Furthermore, the network monitoring unit 3 can fully display the operation status of the aquaculture farm P, and the user can perform power monitoring on the breeding equipment 1 and initiate a warning message when the breeding equipment 1 is not normally activated or closed. Once the breeding equipment 1 should be closed and not closed or should be started without being activated, it is easier to be discovered and repaired in time. Compared with the traditional, it depends on visually confirming the operation status of the breeding equipment 1 and increasing the labor cost or The risk of human error can be generated, which has the effect of saving energy and reducing carbon and saving farming costs.

In addition, when the network monitoring unit 3 detects that the power state of any of the breeding equipment 1 is abnormal or does not start or close properly, The transceiver terminal 32 sends a warning message to the user to notify the user that the breeding equipment 1 may be in a fault condition. Once the user receives the warning message, the user can immediately perform related maintenance, instead of relying on the manpower to discover the breeding. If equipment 1 fails, it may happen that the appliance has burned out or the fry has died. Accordingly, the invented aquaculture system has the effect of greatly improving safety.

In summary, the aquaculture system of the present invention is provided for the user to log in to the network monitoring unit 3 anytime and anywhere to inquire about the operation of each of the aquaculture farms P, and has the effect of improving management efficiency. Furthermore, the aquaculture system of the present invention cooperates with the network monitoring unit 3 to monitor the operation state of each of the breeding equipment 1 in the aquaculture farm, thereby saving human resources and avoiding possible loss caused by human error. To achieve the effect of saving farming costs. In addition, when the aquaculture system of the present invention detects that the operation state of the breeding equipment 1 is abnormal, a warning message is sent through the network monitoring unit 3 to remind the user to perform related processing, which has the effect of improving system security.

While the present invention has been disclosed in the above embodiments, it is not intended to limit the scope of the present invention. The scope of protection of the invention is therefore defined by the scope of the appended claims.

〔this invention〕

1‧‧‧ farming equipment

11‧‧‧Drainage system

111‧‧‧ controlled end

12‧‧‧ pumping motor

121‧‧‧ controlled end

13‧‧‧Water machine

131‧‧‧controlled end

14‧‧‧Feeding machine

2‧‧‧Power Monitoring Module

21‧‧‧Information output

3‧‧‧Network monitoring unit

31‧‧‧ Data collection end

32‧‧‧User transceiver

4‧‧‧Environmental parameter monitoring module

41‧‧‧Fish length detector

42‧‧‧Water level detector

43‧‧‧Information output

5‧‧‧Water quality parameter monitoring module

51‧‧‧Water temperature sensor

52‧‧‧pH sensor

53‧‧‧ Conductivity sensor

54‧‧‧Dissolved oxygen rate sensor

55‧‧‧Information output

P‧‧‧Aquaculture farm

Figure 1: System architecture diagram of the first embodiment of the aquaculture system of the present invention

Figure 2: Control flow chart of the first embodiment of the aquaculture system of the present invention

Figure 3: System architecture diagram of the second embodiment of the aquaculture system of the present invention

Figure 4: Control flow chart of the second embodiment of the aquaculture system of the present invention

1‧‧‧ farming equipment

11‧‧‧Drainage system

111‧‧‧ controlled end

12‧‧‧ pumping motor

121‧‧‧ controlled end

13‧‧‧Water machine

131‧‧‧controlled end

14‧‧‧Feeding machine

2‧‧‧Power Monitoring Module

21‧‧‧Information output

3‧‧‧Network monitoring unit

31‧‧‧ Data collection end

32‧‧‧User transceiver

4‧‧‧Environmental parameter monitoring module

41‧‧‧Fish length detector

42‧‧‧Water level detector

43‧‧‧Information output

5‧‧‧Water quality parameter monitoring module

51‧‧‧Water temperature sensor

52‧‧‧pH sensor

53‧‧‧ Conductivity sensor

54‧‧‧Dissolved oxygen rate sensor

55‧‧‧Information output

P‧‧‧Aquaculture farm

Claims (7)

An aquaculture system, disposed in an aquaculture farm, comprising: at least one culture equipment for performing the operations required for aquaculture operations; and a power monitoring module coupled to the culture equipment to sense the culture equipment Power information, the power monitoring module has an information output terminal for outputting power information of the breeding equipment; and a network monitoring unit having a data collecting end and a user receiving end, the data collecting end coupled to the power monitoring The information output end of the module is configured to receive power information of the breeding equipment, calculate the power consumption state of the breeding equipment, and determine whether the working state of the breeding equipment is normal, and the user transceiver end is provided for the user to communicate through a network The method is: logging in the network monitoring unit to read the operating state of the breeding equipment; wherein, the method further comprises an environmental parameter monitoring module for sensing the environmental condition of the aquaculture farm, the environmental parameter monitoring module has an information output The end is configured to be coupled to the data collection end for outputting the sensed environmental condition information to the network monitoring unit for the user to board Reading; wherein the environmental parameter monitoring module comprises a fish length detector and a water level height detector, wherein the fish length detector is configured to measure and calculate the length data of the aquatic organism cultured in the aquaculture site And determining whether the difference in body length of the aquatic organism cultured in the aquaculture site reaches the pooling operation standard, the water level height detector is configured to detect the water level height information of the aquaculture farm, and determine whether the water level height is Abnormal, and the breeding device comprises a pumping motor and a drainage system, and when the water level detector determines that the water level is abnormal, controlling the pumping motor or the A drainage system to regulate the water level of the aquaculture system. The aquaculture system as described in claim 1, wherein the water quality parameter monitoring module is further configured to sense the water quality parameter of the aquaculture farm, the water quality parameter monitoring module has an information output end for coupling The data collection end is used to output the sensed water quality parameter information to the network monitoring unit for the user to log in and read. The aquaculture system of claim 2, wherein the water quality parameter monitoring module comprises at least one water quality sensor for detecting water quality parameter information of the aquaculture farm, and determining the water quality parameter accordingly Whether the abnormality, and the breeding equipment comprises a pumping motor and a drainage system, when the water quality sensor determines that the water quality parameter is abnormal, the pumping motor and the drainage system are controlled to perform a water exchange operation on the aquaculture farm. The aquaculture system of claim 3, wherein the water quality sensor comprises a dissolved oxygen rate sensor for detecting the dissolved oxygen amount of the aquaculture farm, and determining whether it is too low, And the breeding device further comprises a water machine. When the dissolved oxygen rate sensor determines that the dissolved oxygen rate is too low, the water pump is controlled to perform an aeration operation on the aquaculture farm. The aquaculture system according to claim 1, 2, 3 or 4, wherein the electricity state of the culture device comprises a voltage value and a current value, and the network monitoring unit is based on the voltage value, the current value, and the The switch state of the culture equipment determines whether the operation state of the culture equipment is normal. When the network monitoring unit determines that the operation state of the culture equipment is abnormal, a warning message is sent through the user transceiver. For example, the aquaculture system described in claim 1, 2, 3 or 4, wherein the network communication method is wired network communication. For example, the aquaculture system described in claim 1, 2, 3 or 4, wherein the network communication method is wireless network communication.