It is estimated by the year 2030 there will be a global skilled labor shortage of up to 85 million jobs, which equates to $8.5 trillion, according to a recent Korn Ferry report. Many of these jobs will be in the industrial and service sectors where the Covid pandemic has exposed weaknesses in global supply chains and labor pools. Unmanned aerial vehicles (UAVs) and robots can alleviate this situation by efficiently automating manual tasks.
Today, UAVs are being quickly ushered into service for a host of unique and mission-critical applications, including security/surveillance, parcel delivery, agriculture, defense and even natural disaster recovery and humanitarian aid delivery missions. As we look a few years into the future, we can see UAVs assuming greater roles in more hazardous types of applications such as high-voltage wire inspection, bridge/tower inspection and commercial shipping hull inspection/repair. Using UAVs for these types of applications has several benefits, including faster response times and real-time data gathering. More importantly, the use of unmanned systems for high-risk activities currently performed by human workers eliminates the risk of employee injury, collateral damage and associated liability costs.
As the global economy becomes more integrated and interdependent, the demand for consumer and durable goods is growing exponentially. As a result of this explosive demand, today’s factories are finding it difficult to source, manufacture and deliver goods in a timely fashion. That’s where enlisting the services of robots comes in. Robots excel at routing tasks that require limited decision making. Robots can operate for weeks on end with predictable and repeatable results, dramatically improving efficiency and increasing throughput. The rapid adoption of robots and other automated systems is being driven by consumer demand with no end in sight.
In order for UAVs and robotics to realize widespread deployment, we need to rethink their most impactful limitation—power. How to power them to achieve longer flight times while carrying heavier payloads or stay online to meet production demands using a variety of power sources ranging from onboard batteries, tethered power sources or alternative energy sources like hydrogen fuel cells and renewable energy like solar, wind and wave power.
When we speak with customers, they typically are trying to fit the power supply into a very small space. Size and weight are always a priority for them. So, power modules are a great solution. They are thermally-adept, compact and deliver a lot of power for mobile applications.
That’s where dense power delivery networks come into play. If power is a limiting function of many mobile applications, then it can also be an enabler to innovation if it is used properly.
Module-based solutions offer a high-level of integration at extremely high efficiencies, making it possible to squeeze the most out of your power source using a much smaller footprint than conventional power topologies. This paradigm shift in power delivery means UAV and robotics designers can accommodate more features, functions and higher operating voltages in their designs without having to make any compromises.
By Tom Curatolo Senior Director, Applications Engineering, Vicor