AMRs and the Future of Fruit and Vegetable Preserving and Specialty Food Manufacturing
Overview
As innovations in Autonomous Mobile Robots (AMRs) take center stage in the fruit, vegetable, and specialty foods industry, will we witness a dramatic shift in the way products are preserved and manufactured? Growing evidence suggests so. With an anticipated growth of up to $23.1 billion by 2025 for Global Food Robotics, employing AMRs in food production could save up over 3,000 hours of human labor annually. Furthermore, there is an expected 80% reduction in product damage from handling or preserving perishable items.
Economic Impact of AMRs
The role of AMRs in food processing is not merely technological; it delivers enormous economic benefits too. Food Robotics market expected to grow at a CAGR of 20.9% suggests that businesses using AMRs can significantly reduce overhead costs and boost production. Moreover, by saving over 3,000 hours of human labor annually through automation, these businesses can reinvest human resources into roles that demand creativity and strategic thinking.
Improving Quality and Reducing Product Loss with AMRs
Quality control is a crucial aspect of food preservation and specialty food manufacturing. With AMRs integrated into these processes, the probability of error is significantly reduced, culminating in an expected 80% reduction in product damage. Also, AMRs are less likely to contribute to the cross-contamination of food products, promoting improved sanitation and hygiene standards while reducing food wastage.
Reshaping Jobs With AMRs
Contrary to popular belief, the use of AMRs is not making human labor redundant; instead, it is reshaping the labor economy. With the automation of repetitive and mundane tasks, the human workforce can concentrate on more complex aspects like quality assurance, customer service, and product development. This optimizes productivity and fosters greater job satisfaction.
Key Takeaways
- AMRs could revolutionize the food manufacturing scene by boosting production efficiency and minimizing error.
- The economic advantages of using AMRs is immense, with marked reduction in labor & production costs and time efficiency.
- The probability of human error is significantly reduced with AMRs, resulting in less product damage & food wastage.
- AMRs are enabling businesses to repurpose their human resources for jobs that demand creativity and strategic thinking.
Here at 3Laws Robotics, we are committed to complement the rising trend of AMRs in the food industry by developing groundbreaking software systems to enhance safety and reliability. Our focus on addressing the challenge of certification, a significant issue for many robotics companies, sets us apart.
Our innovative software, 3Laws Supervisor, simplifies the certification process through its robust safety features, providing clear evidence of system robustness. This software, developed on Control Barrier Functions technology, is unique in its mathematically provable safety traits.
We have proven use cases of our technology in various industries. For example, we helped an autonomous forklift customer achieve a remarkable 40% efficiency gain, that led to a payback period of just six months. Besides this, our technology is being lauded for promoting safe human-robot interactions, which is a burgeoning requirement for collaborative robotics solutions.
3Laws is your ideal partner for navigating through dynamic environments. Our reactive collision avoidance capabilities empower robots to efficiently adapt to unpredictable surroundings. Moreover, we strive to enhance operational efficiency by curbing unnecessary stops or collisions, thus reducing downtime.
With our real-time autonomy stacks' guardrails, robots can operate at their peak capabilities while still ensuring optimum safety. Our software adapts to various platforms and is compatible with popular robotics middleware such as ROS and ROS2.
Choose 3Laws and transcend traditional e-stop safety methods. Our proactive approach to safety enables your robots to fulfill their full potentials while ensuring dynamic, predictive safety — all of this can be safety certified, aligning with ISO 3691-4 and ISO 26262 standards.