CN212009403U

CN212009403U - Intelligent shrimp pond culture system

Info

Publication number: CN212009403U
Application number: CN201921208006.2U
Authority: CN
Inventors: 许振龙; 欧茂杰; 陈嘉宏; 曾群智; 吴泽楷; 林铭炫
Original assignee: Guangdong Institute of Science and Technology
Current assignee: Guangdong Titan Intelligent Power Co ltd
Priority date: 2019-07-30
Filing date: 2019-07-30
Publication date: 2020-11-24
Anticipated expiration: 2029-07-30

Abstract

The utility model discloses an intelligent shrimp pond culture system, which comprises a power module, a Zigbee module, a WIFI router, a mobile intelligent terminal, an aerator, a feeder, a turbidity sensor, an illumination sensor, a temperature sensor, an oxygen content sensor and a ph tester; the power supply module supplies power to the Zigbee module, and the Zigbee module is respectively connected with the aerator, the feeder, the turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor and the ph tester in a power supply, control and data transmission way; the Zigbee module is in communication connection with the WIFI router, and the mobile intelligent terminal is in communication connection with the WIFI router. The utility model discloses a wireless sensing technology, networked management method manage, monitor breeding environment, quality of water, temperature etc.. Meanwhile, the automatic aerator and the feeder can be controlled to operate at any time and any place, and the yield is greatly improved on the basis of ensuring the quality.

Description

Intelligent shrimp pond culture system

Technical Field

The utility model relates to an automatic control technical field, concretely relates to shrimp pond intelligence farming systems.

Background

In recent years, with the improvement of living standard of people, the demand of aquatic products is increased year by year, and the traditional culture mode cannot meet the culture mode with large density and high yield.

In the prior art, automatic equipment is introduced to improve the yield of the aquaculture industry and reduce manpower and material resources. However, these automatic equipments are operated individually and independently, and do not form centralized data analysis and unified control management, for example, the oxygen-making equipment needs to be manually judged and the on-off time of the oxygen-making equipment is controlled on site, and the feeding equipment needs to be manually judged and the on-off time of the feeding equipment is controlled on site. That is to say, although some automatic devices are adopted in the existing cultivation technology, the devices need to be controlled on site after technicians know the conditions on site, so that the labor cost is high, and timely and accurate control cannot be achieved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a shrimp pond intelligence farming systems can master shrimp pond key parameter and control corresponding aquaculture equipment's action anytime and anywhere. The utility model discloses realize by following technical scheme:

the utility model provides a shrimp pond intelligence farming systems which characterized in that: the intelligent mobile terminal comprises a power module, a Zigbee module, a WIFI router, a mobile intelligent terminal, an aerator, a feeder, a turbidity sensor, an illumination sensor, a temperature sensor, an oxygen content sensor and a ph tester; the power supply module supplies power to the Zigbee module, and the Zigbee module is respectively connected with the aerator, the feeder, the turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor and the ph tester in a power supply, control and data transmission way; the Zigbee module is in communication connection with the WIFI router, and the mobile intelligent terminal is in communication connection with the WIFI router.

As a specific technical scheme, the oxygen increasing machine comprises a relay, a motor and an oxygen generating mechanism, the relay controls the motor to operate, and the motor drives the oxygen generating mechanism to generate oxygen.

As a specific technical scheme, the feeder comprises a relay, a motor and a feeding mechanism, wherein the relay controls the motor to operate, and the motor drives the feeding mechanism to feed.

As a specific technical scheme, the turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor and the ph tester are respectively arranged at corresponding detection positions in the shrimp pond.

As a specific technical scheme, the temperature sensor adopts a waterproof packaging DS18B20 digital temperature sensor.

As a specific technical scheme, the Zigbee module is implemented by a cc2530F256 single chip microcomputer.

As a specific technical scheme, the intelligent shrimp pond breeding system further comprises a warning module which is connected with the Zigbee module and is controlled by the Zigbee module to give an alarm.

As a specific technical scheme, the intelligent shrimp pond breeding system further comprises a temperature adjusting device which is connected with the Zigbee module and is controlled by the Zigbee module to adjust the water temperature and the illumination of the shrimp pond.

As a specific technical scheme, the intelligent shrimp pond breeding system further comprises an illumination adjusting device which is connected with the Zigbee module and is controlled by the Zigbee module to adjust the water temperature and illumination of the shrimp pond.

The utility model discloses an advanced management methods such as wireless sensing technique, networked management carry out all-round management, monitoring to aquaculture environment, quality of water, temperature etc. have functions such as data real-time collection and analysis, food are traced to source, production base remote monitoring. Meanwhile, the automatic aerator and the feeder can be controlled to operate at any time and any place, and the yield is greatly improved on the basis of ensuring the quality.

Drawings

Fig. 1 is a block diagram of the shrimp pond intelligent breeding system provided by the embodiment of the utility model.

Fig. 2 is a schematic circuit diagram of a Zigbee module in an embodiment of the present invention.

Fig. 3 is a schematic circuit diagram of a relay according to an embodiment of the present invention.

Fig. 4 is a schematic circuit diagram of a temperature sensor according to an embodiment of the present invention.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

As shown in fig. 1, the shrimp pond intelligent breeding system provided by this embodiment includes a power module, a Zigbee module, a WIFI router, a mobile intelligent terminal, an oxygen increasing machine, a feeder, a turbidity sensor, an illumination sensor, a temperature sensor, an oxygen content sensor, and a ph (ph value) tester. The turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor and the ph tester are respectively arranged at corresponding detection positions in the shrimp pond and used for collecting corresponding data of the water for shrimp pond culture.

The power module is a battery module or a direct current power module converted by mains supply, is electrically connected with the Zigbee module, supplies power to the Zigbee module, and supplies power to other devices needing power supply under the control of the Zigbee module.

The Zigbee module is a communication and control module based on an IEEE802.15.4 standard low-power consumption local area network protocol, can realize short-distance and low-power consumption wireless communication, and is characterized in that: the data transmission rate is low: the power consumption is low: the cost is low: the network capacity is large: the time delay is short. In this embodiment, the Zigbee module is connected to the aerator, the feeder, the turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor, and the ph tester for power supply, control, and data transmission, so that data acquisition of each detection component and control over the operation of each execution component are achieved. Referring to fig. 2, the Zigbee module in this embodiment is implemented by a cc2530F256 single chip microcomputer.

In addition, Zigbee module and WIFI router communication connection, mobile intelligent terminal can be the cell-phone that is integrated with corresponding management APP, and corresponding management APP's interface provides the control button etc. to the demonstration of data collection, the settlement and the execution module of relevant threshold value. However, it should be noted that managing the APP accordingly is not the innovative point to be protected by the present application. In the application, the Zigbee module and the WIFI router are connected with and controlled by the mobile intelligent terminal. As long as the mobile phone control end is connected with the WIFI router, the real-time data transmitted by the sensor can be received, and the environment variable is adjusted according to the life habit of the cultivated product.

The intelligent shrimp pond culture system provided by this embodiment further includes a warning module, which is connected to the Zigbee module, and when the collected real-time data exceeds the set threshold, the warning module is started to give an alarm for prompting (sounding a buzzer, prompting by a mobile intelligent terminal) or automatically execute a related program. For example, when the oxygen content in the shrimp pond is reduced, the system can automatically turn on oxygen or give an alarm for prompting.

The intelligent shrimp pond culture system provided by the embodiment further comprises a temperature adjusting device and an illumination adjusting device, which are respectively connected with the Zigbee modules, and are controlled by the Zigbee modules to respectively adjust the water temperature and illumination of the shrimp pond.

In this embodiment, the oxygen-increasing machine includes relay, motor and system oxygen mechanism, and the relay receives the instruction of Zigbee module and controls the operation of motor, and the motor drive system oxygen mechanism makes oxygen. Similarly, the feeder includes relay, motor and feeds and eats the mechanism, and the relay receives the instruction of Zigbee module and control the operation of motor, and the motor drive feeds and eats the mechanism and feed. The feeding device can save manpower for manual feeding and achieve the intelligent purpose, can set feeding time in each time period, can automatically feed food when the time is up, and can be networked with the mobile intelligent terminal to control whether to feed food or not; the aerator is also in the same control mode. The circuit schematic of the relay is shown in fig. 3.

In this embodiment, the temperature sensor is a waterproof packaged DS18B20 digital temperature sensor, and a schematic circuit diagram thereof is shown in fig. 4. Temperature is one of the important physical factors affecting aquaculture. The water temperature not only influences the water quality condition of the water body, but also influences the growth and development of the cultured objects. Different aquatic organisms have different adaptability to water temperature, and in a suitable temperature range, the higher the water temperature is, the larger the food intake of a culture object is, and the smaller the bait coefficient is; generally, the higher the water temperature, the faster the growth rate of the aquatic organisms. The temperature sensor measures the water temperature of the shrimp pond and transmits the temperature parameter to the mobile intelligent terminal through the Zigbee module, and a user can adjust the water according to the parameter.

In addition, because the shrimp of breeding has the requirement to quality of water, so, this scheme has added a turbidity sensor, monitors quality of water to prevent that quality of water goes wrong and not discover in time and cause shrimp grower's economic loss. In addition, because the young shrimp has certain requirements on illumination, an illumination sensor is specially added, the illumination intensity is monitored in real time, and the shrimp farmer can act according to the illumination intensity. The time and intensity of the illumination can influence the breeding cycle and the body surface color of the breeding objects, the breeding cycle determines the yield, and the body surface color and the quality have close relationship.

In this embodiment, the shrimp pool can be a culture pond, and can also be box bodies of different specifications made of materials such as glass, plastics, metal and the like

The above embodiments are merely for full disclosure and are not intended to limit the present invention, and all changes that can be made without creative work based on the inventive idea and the equivalent technical features should be considered as the scope of the present disclosure.

Claims

1. An intelligent shrimp pond culture system comprises a power supply module, a Zigbee module, a WIFI router, a mobile intelligent terminal, an aerator, a feeder, a temperature sensor, an oxygen content sensor and a ph tester; the power supply module supplies power to the Zigbee module, and the Zigbee module is respectively connected with the aerator, the feeder, the temperature sensor, the oxygen content sensor and the ph tester; the Zigbee module is in communication connection with the WIFI router, and the mobile intelligent terminal is in communication connection with the WIFI router; the shrimp pond is characterized in that the shrimp pond is a box body made of glass or plastic materials, the culture system further comprises a turbidity sensor and an illumination sensor, and the Zigbee module is connected with the turbidity sensor and the illumination sensor respectively.

2. The shrimp pool intelligent aquaculture system of claim 1 wherein: the oxygen increasing machine comprises a relay, a motor and an oxygen generating mechanism, wherein the relay controls the motor to operate, and the motor drives the oxygen generating mechanism to generate oxygen.

3. The shrimp pool intelligent aquaculture system of claim 1 wherein: the feeder includes relay, motor and feeds and eats the mechanism, and the operation of relay control motor, motor drive feed and eat the mechanism and feed and eat.

4. The shrimp pool intelligent aquaculture system of claim 1 wherein: the turbidity sensor, the illumination sensor, the temperature sensor, the oxygen content sensor and the ph tester are respectively arranged at corresponding detection positions in the shrimp pond.

5. The shrimp pool intelligent aquaculture system of claim 1 wherein: the temperature sensor adopts a waterproof packaging DS18B20 digital temperature sensor.

6. The shrimp pool intelligent aquaculture system of claim 1 wherein: the Zigbee module is realized by a cc2530F256 singlechip.

7. The shrimp pool intelligent aquaculture system of claim 1 wherein: the intelligent shrimp pond culture system further comprises a warning module which is connected with the Zigbee module and is controlled by the Zigbee module to alarm.

8. The shrimp pool intelligent aquaculture system of claim 1 wherein: the intelligent shrimp pond breeding system further comprises a temperature adjusting device which is connected with the Zigbee module and is controlled by the Zigbee module to adjust the water temperature and the illumination of the shrimp pond.

9. The shrimp pool intelligent aquaculture system of claim 1 wherein: the intelligent shrimp pond breeding system further comprises an illumination adjusting device, the illumination adjusting device is connected with the Zigbee module, and the temperature and illumination of the shrimp pond are controlled by the Zigbee module to be adjusted.