The Internet of Things technology has been widely used at this stage. It uses various technologies to perceive, transmit, process and feedback information. Its biggest feature is the diversity, decentralization, intelligence and real-time nature of perception. Diversity is manifested by many perception objects, many perception parameters, and large capacity; decentralization means that people and things, things and things are usually more scattered; intelligence means that data needs to be analyzed and processed; practicality means real-time perception, transmission and Processing information.
The current Internet of Things is different from the earlier Internet of Things. The early Internet of Things used RFID technology to identify and perceive the static characteristics of items, and used the Internet for information transmission; the current Internet of Things obtains various information through various information-aware devices such as RFID, photoelectric sensors, global positioning systems, etc., based on the Internet Carry out information transmission and processing to realize the communication and interaction between people and things, things and things. The Internet of Things involves multiple disciplines and technologies, and needs advanced communication technologies as support.
The main processes of the Internet of Things work are induction, transmission and intelligence: first, the static and dynamic attributes of objects are sensed, and environmental variables are sensed; then long-distance, broadband, and reliable information transmission; and finally, big data is real-time, Fast and intelligent processing.
Optical fiber communication and optical fiber sensing technology will play an important role in the field of Internet of Things. Optical fiber is a light transmission medium made of silica glass material with a diameter of 0.125mm and a length from a few meters to tens of kilometers. The loss of the optical fiber is very small. In the 1.55um band, the loss can be as low as 0.2dB per kilometer. About 99% of the incident light can pass through the 1 kilometer of optical fiber.
The optical fiber has broadband characteristics, and various sensors can be reused in one optical fiber for detection and transmission. Optical fiber sensor has the advantages of small size, light weight, strong durability, anti-electromagnetic interference, no power supply for the sensor head, safe use (good insulation, no risk of fire and explosion), remote telemetry, multi-point multiplexing, distributed measurement, etc. As a sensor, fiber optic materials have unique advantages.
The principle of optical fiber sensing is to detect changes in external physical quantities by detecting changes in the intensity, phase, frequency / wavelength, and polarization of light waves transmitted in the optical fiber. Fiber optic sensors can be made into discrete, quasi-continuous and distributed sensor measurement systems. Various variables such as temperature, displacement, acceleration, pressure, strain, electric field, magnetic field, rotation, gas concentration, flow rate, corrosion, etc. can be measured.
As early as 2008, IBM proposed the concept of a smart earth, and recommended that the government invest in the construction of a new generation of smart infrastructure. The next stage of the IT industry's mission is to apply a new generation of information technology to various industries, embed and equip sensors into various objects such as power grids, transportation, bridges, tunnels, buildings, dams, water and oil pipelines, urban infrastructure, etc. , And connected through the network to form the Internet of Things.
The application range of fiber optic sensors is very wide, mainly in the following aspects:
The application of interferometric gyroscopes and grating pressure sensors in bridges, dams, oil fields, etc. in urban construction. Fiber optic sensors can be pre-buried in concrete, carbon fiber reinforced plastics, and various composite materials to test stress relaxation, construction stress, and dynamic load stress to evaluate the structural performance of the bridge during the short-term construction phase and long-term operation.
In the power system, parameters such as temperature and current need to be measured, such as the detection of the temperature in the stator and rotor of high-voltage transformers and large motors. Because electrical sensors are susceptible to interference from electromagnetic fields, they cannot be used in such occasions and can only be used Fiber Optic Sensor. For example, the distributed optical fiber temperature sensor is a high-tech that has been developed in recent years to measure the spatial temperature distribution in real time.
Used for temperature measurement of the production process and equipment of flammable and explosive materials. The optical fiber sensor is essentially a fire and explosion-proof device. It does not require explosion-proof measures and is very safe and reliable. Compared with electrical sensors, it can both reduce costs and increase sensitivity.
In addition, it can also be used in railway monitoring, rocket propulsion systems, and oil well detection.
In short, the Internet of Things and optical fiber sensing have a complementary and mutually reinforcing role. Optical fiber also has the significant advantages of broadband, large capacity, long-distance transmission, and the realization of multi-parameter, distributed, and low energy consumption sensing. Optical fiber sensing can continuously absorb new technologies of optical fiber communication (such as new semiconductor light sources, new optical fibers), new devices, and various optical fiber sensors are expected to be widely used in the Internet of Things. Optical fiber technology has a very broad application prospect in the Internet of Things. The all-optical Internet of Things is expected to appear in the future and become a new form of Internet of Things.
The main function of the Solar Charge Controller is to manage the charging and discharging process between the Solar Panel and the battery in the solar power generation system. Its main function is to protect the battery from overcharge and over-discharge damage, ensure battery charging efficiency, and stabilize the operation of the solar power generation system.
Main effect:
Charge control: The solar charge controller controls the charging process by monitoring the voltage and current generated by the solar panel to ensure that the battery is charged at the appropriate voltage and current to extend the battery life.
Overcharge protection: The solar charge controller can monitor the charging status of the battery, and when the battery is fully charged, it will automatically stop charging to avoid battery damage caused by overcharging.
Over-discharge protection: The solar charge controller can monitor the discharge state of the battery. When the battery power is lower than a certain level, it will automatically stop discharging to avoid battery damage caused by over-discharge.
Differences from other charge controllers:
The solar charge controller is a charge controller specially designed for solar power generation systems, the main differences are as follows:
Applicable Energy: The solar charge controller is suitable for solar power generation systems, mainly used to manage the charging and discharging process between solar panels and batteries. While other charge controllers may be suitable for different energy generation systems, such as wind energy, hydro energy, etc.
Charging characteristics: The solar charge controller is optimized for the characteristics of the solar panel, and can control the charging process according to the output power and voltage characteristics of the solar panel. Other charge controllers may be optimized for different types of energy generation characteristics.
Protection function: Solar charge controllers usually have overcharge protection and over-discharge protection functions to ensure the safe charging and discharging of batteries. Other charge controllers may have different protection functions, depending on the needs of the application scenario.
Overall, the main role of the solar charge controller is to manage the charging and discharging process in the solar power generation system, protect the battery from damage, and stabilize the system's operation. Compared with other charge controllers, it is optimized for the characteristics of solar power generation systems and has unique functions such as overcharge protection and over-discharge protection to meet the needs of solar power generation systems.
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