Rescue robots are becoming more commonplace today, but what are their capabilities? They can carry heavy equipment, crawl through collapsed tunnels, and even transport wounded victims. In the years to come, these robots will become an indispensable part of our emergency response system.
Read on to learn more about the different ways they can help. In 2022, they are expected to play an increasingly important role in disaster relief.
Rescue robots can carry heavy equipment.
Rescue robots weigh around 120 kilograms, making them easy to carry. They can handle different processes, such as carrying people and heavy equipment and are designed to make the task simpler for rescue teams. Rescue robots can handle different terrains, including steep slopes and uneven ground, and are flexible enough to move on rough surfaces. In 2022, rescue robots could also be used in disaster relief efforts, such as removing explosives from buildings.
Increasing defence spending, terrorism, and technological advancements have contributed to the growth of the global search and rescue robots market in recent years. Several global and regional vendors have entered the field, contributing to market growth. These vendors are competing on cost, product quality, and reliability. The report provides an outlook of the market through 2022. Rescue robots are projected to continue to make progress over the next decade.
Rescue robots will have the capacity to extend thousands of times their original length and will move independently without human assistance. Some robots can even form tool shapes, such as shovels and lift objects to reach difficult locations. This technology is proving to be an indispensable tool during emergencies. They can also be safer than humans in several ways. So, when they are in use, they will save lives and the environment.
In the next few years, the market for rescue robots is expected to grow at the fastest rate in the Asia-Pacific region. APAC countries spend a lot of money on search and rescue robots, with China spending more than USD 215 billion on the military in 2016.
Aside from carrying people and heavy equipment, rescue robots can collect structural data on collapsed buildings. In Italy, a partially collapsed church was recently used by a TRADR and drone. The prototype gained attention from firefighters in other European countries. RHex also speaks English and is capable of understanding simple voice commands. Eventually, robots may also be able to speak languages other than English.
They can crawl through collapsed tunnels.
Rescue robots are becoming increasingly common after the devastating earthquakes and natural disasters in Japan and other countries. Their advanced capabilities and ability to traverse various obstacles make them an invaluable aid in disaster response. However, while robots are already being used to search for survivors, their mobility still poses challenges. For example, they cannot turn around in the narrow spaces between rubble and structures and their paths are frequently filled with twists and turns. Also, rescuers must program robotic vehicles to drive over various surfaces, including dust, water, and mud. Additionally, they must provide valuable information about the victims to locate them.
One recent natural disaster left 12 trapped miners dead. The explosion at Sago Mine in Talmansville, West Virginia, was the first of its kind. Although the exact cause of the explosion has not been determined, state and federal mining experts are starting an investigation to find the root cause of the disaster. Rescue robots could save countless lives in the future. They could also assist rescue teams with other tasks, such as clearing debris and mapping the scene.
In some disasters, large robots can’t navigate the area. However, small robots can be carried to the site and be used to assess the damages. By using a combination of manoeuvrability and mobility, robots could be sent into disaster zones. A large robot would struggle to survive a collapsed tunnel so that these smaller ones could be used for other purposes. The technology is already available and can be developed in months.
One example of a disaster response robot is WALK-MAN. This robotic system can perform many dangerous tasks and crawl through collapsed tunnels. It can lift collapsed masonry, walk over obstacles, navigate cluttered spaces, and operate tools. WALK-MAN is capable of working autonomously and with remote control. As it develops, it can walk on all four wheels. A robot like this will eventually become an essential aid for disaster relief efforts.
They can transport wounded victims.
By 2022, a robot called the “RescueBot” could be helping human rescue workers in disaster situations by transporting wounded victims to safety. The robot was initially designed as a helper to rescue workers but ended up expanding its role within the team. The project involved the Dortmund Fire Department and the forces of the Italian fire brigade, allowing researchers to learn from the real-world experience of emergency responders. The robot must work hand in hand with human rescuers in disaster situations. It can scour the sky and even grab and grasp fragile objects without damaging them.
In the future, robots will become essential members of first responders. Unlike humans, robots can search for victims in places where rescuers can’t go. They will report to human operators the progress and location of a rescue operation. They will be equipped with sensors and cameras to help rescue teams locate victims. Some robots will be remotely controlled, while others will be autonomous.
Meanwhile, other robotics are also being developed to aid the human armed forces. The U.S. Army has long envisaged using these robots in war zones. They could aid in trauma and battlefield medicine, helping to reduce human fatalities. These technological advances will ensure that more people will be saved and less need is put under the care of medical staff. While this new technology has a long way to go, it could make life easier for our soldiers and first responders.
A large walking robot could change how we search for disaster victims. It could help carry people safely and quickly from a deadly situation. It could also improve the process of damage assessment for communities. This rapid assessment would be invaluable for the recovery effort and speed up the recovery process. The first robots could help save lives and prevent the need for additional amputations. The benefits of such technology go beyond humanitarian concerns.
They can assess a scene.
Rescue robots have been developed and tested in various types of environments. In the World Trade Center disaster, they were used to test their abilities to detect victims and assess unsafe environments. They also tested how well their sensors covered the scene and what would happen if a victim were to die. The robots are not yet perfect, and they still need to undergo several improvements before they can be considered a viable option for rescue work.
To create an insect robot, researchers studied the movements of real insects. They found that insects can withstand pressure up to 900 times their weight. One prototype of an insect robot is palm-sized and equipped with a layered plastic shell to prevent damage. While drones have been used for rescue efforts for over a decade, they’re not ideal for finding survivors trapped in the rubble. Rescue robots can evaluate a scene quickly and accurately and could help save lives if they can reach them.