The latest estimates suggest that by 2050 we will need twice as much energy as our existing energy sources. The harmful effects of fossil fuels and the looming shortages have prompted people to accelerate their search for environmentally friendly and sustainable new energy sources.
The International Energy Agency (IEA) says their route is correct and the most important is technological innovation. The clean energy sector has now attracted a lot of investment, such as renewable energy, high energy efficiency and low pollution technologies. But analysts expect real investment surges in the sector over the next 20 to 30 years.
The transformation is going on. In the 20th century, when fossil fuels became the driving force of the first industrial revolution, our economy was characterized by a large amount of artificial labor, large factories and the production of material materials. At that time we thought that the resources in the world seemed to be infinite. Now we are experiencing resource depletion, the constraints imposed by fossil fuels, and climate change issues that have forced us to reconsider our energy consumption and turn to a more environmentally friendly approach.
Now, technological innovation drives our economic development and improves the quality of our lives through non-material materials such as services and content. Technological innovation will also be the key to solving energy challenges. The only way to solve this challenge is to develop renewable energy on a large scale and save energy in all conceivable ways.
The electronics industry will play an important role in this transformation. Technologies used to generate renewable energy, such as photovoltaic systems, non-food biofuels, wind energy, and hybrid vehicles, have received the attention of leading chip companies.
Technical solutions However, the introduction of renewable energy resources to generate electricity will present new challenges to existing power network infrastructure:
How to solve the increase in the number of loads, how to integrate various non-local energy sources into the same power grid, how to deal with fluctuations between different energy sources (considering wind power plants), how to transmit electricity more efficiently, how to ensure power The high reliability and high stability of the supply are new challenges we face.
These challenges are driving the “smart grid†to move forward. Smart grids will help achieve efficient integration of renewable and traditional energy sources, managing power distribution based on resource availability and user needs. As with most of the emerging new energy-saving technologies, the development of smart grids will be driven by advances in power conversion systems, particularly power electronics. The result will be an increase in the efficiency and reliability of the energy supply, while the energy consumption will decrease.
In addition to changing behavior and promoting energy-saving activities in residential and office buildings, new technology solutions such as sensor-based and efficient ICT (Information and Communication Technology) systems, more efficient power conversion, and solid-state lighting, Will help reduce energy consumption.
The role of power electronics technology for generating and converting energy power electronics covers a wide range of applications such as ICT power supplies, motor drives, solar converters, and hybrid electric vehicles. Today, more than 60% of electrical energy flows through silicon-based devices. Improving the performance of power electronics systems seems to be increasingly becoming a key factor in significantly reducing power consumption.
More efficient, faster, and more reliable solid-state devices that can operate at high voltages, high current densities, and high temperatures must be developed. This is very challenging for semiconductor developers. Power electronics are approaching the inherent limits of silicon materials.
Further innovations and improvements in energy-generating devices will require the use of wide-bandgap semiconductors, which can be used to produce devices with higher breakdown voltages. Among them, the best candidate materials appear to be Group III nitride wide bandgap materials because they have both high voltage and high electron speed, which significantly reduces switching and conduction losses at high voltages.
The TPU materials type raw cable jacket can guarantee longer lifetime and quality. Coiled cable can be used to carry electrical currents as well as data and signal for telecommunications applications. This versatility makes coil cords ideal for use in environments that are often too rough for non-coiled cable.
It has the ability to extend beyond the natural length at rest, which can be a real space-saving feature. These cords are flexible beyond simple extending and retracting in that they can also be pulled, bent, and twisted without experiencing the metal fatigue of a straight cable.
Flex Coiled Cable Assembly, coiled cable harness, flex coiled wiring cable,High Quality Electrical Wire Harness,light-duty coiled cables
ETOP WIREHARNESS LIMITED , https://www.oemwireharness.com