Solutions to the bottleneck of lithium battery applications

Solving the capacity bottleneck of lithium battery wireless charging applications, a multi-mode plan that is compatible with the advantages of different wireless charging technologies will be the backbone of the future. In view of the lack of unified and standardized wireless charging technology, and the advantages and disadvantages of each specification camp, in terms of skills, the industry has intensified a multi-mode plan to handle the compatibility between different specifications and enable wireless charging products to supply charging power and Free space experience. Wireless charging technologies include magnetic induction (MI) and magnetic resonance (MR). Regardless of the trend of the consumer market, wireless charging has become an inevitable trend. In the next few years, wireless charging will be mainly promoted by mobile phone manufacturers and will begin to penetrate the mobile market. Later, computer stores with good ecology will follow up, leading to the development of wireless charging technology. From then on, wireless charging will implement a processing plan that supports mobile phones and computers. At that time, there were already many wireless power selection rates and potentially all useful market (TAM) reports and studies, but it is not easy to provide accurate market information, because in these guesses, selection rates and skills are crucial parameters . There are two important specifications for magnetic induction technology: Wireless Power Consortium (WPC) and Power Facilities Alliance (PMA), both of which are quite mature and have been used in the consumer market. The Alliance for Wireless Power (A4WP) is the first magnetic resonance specification. It is worth noting that Intel's magnetic resonance wireless charging technology is designed for its own ultra-thin notebook computers and ecosystem. Other companies, such as PowerbyProxi and WiTricity, have established themselves in the industrial and military sectors. In order to know the impact of the specifications and processing methods on the future development direction of wireless charging technology, it is first necessary to know the difference between MI and MR technologies, and then select the specific application processing method after fully knowing and knowing the application/system requirements. Dealing with battery capacity bottlenecks, the wireless charging application head mobile processing plan is the first plan to use wireless charging technology in consumer stores. With Long Term Evolution (LTE) technology, communication speed and bandwidth will not encounter bottlenecks for at least the next few years. The convenient consumer market promotes mobile processing projects, a key element of different mobile processing programs, such as mobile phones, tablets, multimedia players and mobile TVs, etc., transformers and connector interfaces have different requirements to charge mobile devices, There are many connectors and transformers, when we have a universal wireless transformer plus a good infrastructure and ecosystem, and can meet the needs, in cars, cafes, libraries, restaurants, trains, airplanes, offices, conference rooms, etc. Wireless charging can be done anywhere at any time, which can bring the expected convenience. Every two years, the appearance, performance and function of the mobile processing plan will be upgraded. These upgrades will force changes in power requirements, connectors and interfaces, and new transformers. These changes and upgrades have also disrupted the screening and processing of existing transformers. Eliminating transformers and connectors and choosing standardized wireless charging can help reduce e-waste and improve the green certification of mobile devices. Another important element is the improvement of mobile processing methods, such as 1080p selection and 3D display skills. The mobile processing plan will add selected high-resolution rendering skills supported by high-performance graphics controllers and multi-core central processing units (cpu); in addition, integrating increasingly rich mobile processing planning skills, including 3D global positioning system (GPS) Processing plans, high-performance video and audio skills, Near Field Communication (NFC) skills, portable TVs, and high-performance games will increase the demand for device battery power. The power source for mobile processing programs is usually a lithium-ion polymer battery whose energy density has been high for many years. Lithium batteries have been unable to meet the increased power demand due to technological upgrades and the use of different metal treatments to improve efficiency and lifespan. In addition, the batteries must be kept small in size to meet the needs of mobile processing applications. Since the battery capacity per unit volume has reached the limit, the disposal method should achieve a higher battery capacity or increase the charging frequency. Disclaimer: Some pictures and content of the articles published on this site are from the Internet. If there is any infringement, please contact to delete. Previous article: Why can't the electric vehicle battery accurately display the remaining power?