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# LinkPeptide: Revolutionizing Protein Engineering and Therapeutic Development

## Introduction

In the ever-evolving field of biotechnology, LinkPeptide has emerged as a groundbreaking tool that is transforming the landscape of protein engineering and therapeutic development. This innovative technology is paving the way for more efficient, precise, and versatile approaches to designing and synthesizing proteins, which are crucial for a wide range of applications in medicine, agriculture, and industrial processes.

## The Science Behind LinkPeptide

LinkPeptide is a sophisticated platform that leverages advanced computational algorithms and high-throughput experimental techniques to design and optimize peptides and proteins. At its core, LinkPeptide utilizes a combination of machine learning, structural biology, and synthetic biology to predict and generate peptide sequences with desired properties. This allows researchers to create novel proteins that can perform specific functions, such as binding to target molecules, catalyzing biochemical reactions, or modulating cellular processes.

### Key Features of LinkPeptide

– **High Precision**: LinkPeptide’s algorithms are designed to predict peptide structures with high accuracy, reducing the need for extensive trial-and-error experimentation.
– **Versatility**: The platform can be used to design peptides for a wide range of applications, from drug development to enzyme engineering.
– **Speed**: LinkPeptide significantly accelerates the protein design process, enabling researchers to rapidly prototype and test new ideas.
– **Customizability**: Users can tailor the platform to meet specific research needs, whether they are working on therapeutic proteins, industrial enzymes, or synthetic biology projects.

## Applications in Therapeutic Development

One of the most promising applications of LinkPeptide is in the development of new therapeutics. By enabling the design of highly specific and potent peptides, LinkPeptide is helping to address some of the most challenging medical conditions, including cancer, infectious diseases, and autoimmune disorders.

### Cancer Therapeutics

LinkPeptide is being used to design peptides that can selectively target cancer cells while sparing healthy tissues. These peptides can be engineered to deliver cytotoxic agents directly to tumors, enhancing the efficacy of cancer treatments and reducing side effects. Additionally, LinkPeptide is being explored for the development of peptide-based vaccines that can stimulate the immune system to recognize and destroy cancer cells.

### Infectious Diseases

In the fight against infectious diseases, LinkPeptide is facilitating the creation of peptides that can inhibit the replication of viruses or bacteria. For example, researchers are using LinkPeptide to design peptides that can block the entry of HIV into human cells or disrupt the life cycle of antibiotic-resistant bacteria. These peptides have the potential to serve as next-generation antimicrobial agents, offering new hope in the battle against drug-resistant pathogens.

### Autoimmune Disorders

LinkPeptide is also being applied to the development of peptides that can modulate the immune system. By designing peptides that can selectively inhibit or activate specific immune pathways, researchers are working on new treatments for autoimmune disorders such as rheumatoid arthritis, lupus, and multiple sclerosis. These peptides could provide more targeted and effective therapies with fewer side effects compared to current treatments.

## Industrial and Agricultural Applications

Beyond medicine, LinkPeptide is making waves in industrial and agricultural biotechnology. The platform is being used to engineer enzymes with enhanced stability, activity, and specificity, which are essential for various industrial processes, including biofuel production, food processing, and waste management.

### Enzyme Engineering

LinkPeptide is enabling the design of enzymes that can operate under extreme conditions, such as high temperatures or acidic environments, making them ideal for industrial applications. For instance, enzymes engineered using LinkPeptide are being used to break down plant biomass more efficiently, leading to more sustainable biofuel production. Similarly, in the food industry, LinkPeptide-designed enzymes are being used to improve the texture, flavor, and nutritional value of food products.

### Agricultural Biotechnology

In agriculture, LinkPeptide is being used to develop peptides that can enhance crop resistance to pests and diseases. By engineering peptides that can disrupt the life cycle of harmful insects or inhibit the growth of pathogenic fungi, researchers are working on new ways

# BR-25M 4P 1 25kA: The Ultimate Circuit Breaker for High-Current Applications

When it comes to managing high-current electrical systems, the BR-25M 4P 1 25kA circuit breaker stands out as a top-tier solution. Designed to handle demanding environments, this circuit breaker ensures safety, reliability, and efficiency in a variety of industrial and commercial settings.

## Key Features of the BR-25M 4P 1 25kA

The BR-25M 4P 1 25kA is packed with features that make it an indispensable component in any high-current application. Here are some of its standout attributes:

– **High Breaking Capacity**: With a breaking capacity of 25kA, this circuit breaker can handle significant fault currents, ensuring the protection of your electrical system.
– **4-Pole Design**: The 4-pole configuration provides comprehensive protection for all phases and the neutral, making it ideal for three-phase systems.
– **Compact and Durable**: Despite its high performance, the BR-25M 4P 1 25kA is designed to be compact and robust, ensuring long-term reliability even in harsh conditions.
– **Easy Installation**: The user-friendly design allows for quick and straightforward installation, minimizing downtime and labor costs.

## Applications of the BR-25M 4P 1 25kA

The versatility of the BR-25M 4P 1 25kA makes it suitable for a wide range of applications. Here are some of the key areas where this circuit breaker excels:

– **Industrial Plants**: In environments with heavy machinery and high power demands, the BR-25M 4P 1 25kA ensures uninterrupted operation and safety.
– **Commercial Buildings**: From office complexes to shopping malls, this circuit breaker provides reliable protection for large-scale electrical systems.
– **Data Centers**: With the increasing power requirements of data centers, the BR-25M 4P 1 25kA offers the necessary protection to prevent costly downtime.
– **Renewable Energy Systems**: In solar and wind power installations, this circuit breaker safeguards the system against overloads and short circuits.

## Why Choose the BR-25M 4P 1 25kA?

Choosing the right circuit breaker is crucial for the safety and efficiency of your electrical system. The BR-25M 4P 1 25kA offers several advantages that make it the preferred choice for professionals:

– **Reliability**: Built to withstand extreme conditions, this circuit breaker delivers consistent performance over time.
– **Safety**: With its high breaking capacity and robust design, the BR-25M 4P 1 25kA ensures the safety of both equipment and personnel.
– **Efficiency**: The efficient design minimizes energy losses, contributing to overall system efficiency.
– **Compliance**: The BR-25M 4P 1 25kA meets international standards, ensuring compliance with safety and performance regulations.

In conclusion, the BR-25M 4P 1 25kA circuit breaker is a reliable, efficient, and safe solution for high-current applications. Whether you’re managing an industrial plant, a commercial building, or a renewable energy system, this circuit breaker provides the protection and performance you need.

# BR-25M 4P 1 25kA: The Ultimate Circuit Breaker for High-Current Applications

When it comes to managing high-current applications, the BR-25M 4P 1 25kA circuit breaker stands out as a top-tier solution. Designed to handle up to 25kA of interrupting capacity, this circuit breaker is engineered for reliability, safety, and performance in demanding environments.

## Key Features of the BR-25M 4P 1 25kA

The BR-25M 4P 1 25kA boasts a range of features that make it an ideal choice for high-current applications:

– High Interrupting Capacity: With a 25kA interrupting capacity, this circuit breaker can handle significant electrical loads without compromising safety.
– 4-Pole Design: The 4-pole configuration ensures comprehensive protection across all phases, making it suitable for three-phase systems.
– Compact and Durable: Despite its high performance, the BR-25M 4P 1 25kA is designed to be compact and durable, ensuring long-term reliability.
– Easy Installation: The circuit breaker is designed for easy installation, reducing downtime and labor costs.

## Applications of the BR-25M 4P 1 25kA

The BR-25M 4P 1 25kA is versatile and can be used in a variety of high-current applications, including:

– Industrial Facilities: Ideal for protecting machinery and equipment in industrial settings.
– Commercial Buildings: Ensures the safety of electrical systems in large commercial buildings.
– Data Centers: Provides reliable protection for critical infrastructure in data centers.
– Renewable Energy Systems: Suitable for use in solar and wind energy systems where high-current protection is essential.

## Why Choose the BR-25M 4P 1 25kA?

Choosing the BR-25M 4P 1 25kA circuit breaker means opting for a product that combines advanced technology with robust construction. Its high interrupting capacity, 4-pole design, and ease of installation make it a superior choice for any high-current application. Whether you’re managing an industrial facility, a commercial building, or a renewable energy system, the BR-25M 4P 1 25kA delivers unmatched performance and reliability.

In conclusion, the BR-25M 4P 1 25kA circuit breaker is a top-tier solution for high-current applications. Its advanced features, robust design, and versatility make it an essential component for ensuring the safety and reliability of electrical systems in a wide range of environments.

# Revolutionizing Temperature Monitoring: The Power of Fiber Optic Sensing Technology

## Introduction

In the realm of temperature monitoring, the advent of fiber optic sensing technology has marked a significant leap forward. This innovative approach to temperature measurement offers unparalleled precision, reliability, and versatility, making it a game-changer across various industries. From industrial processes to medical applications, fiber optic temperature measurement is setting new standards for accuracy and efficiency.

## Understanding Fiber Optic Temperature Measurement

Fiber optic temperature measurement leverages the unique properties of optical fibers to detect and quantify temperature changes. Unlike traditional methods that rely on electrical signals, this technology uses light to transmit data, resulting in several key advantages:

– Immunity to electromagnetic interference
– High sensitivity and resolution
– Ability to measure temperature in harsh environments
– Distributed sensing capabilities over long distances

## Key Components of Fiber Optic Temperature Sensors

The core components of a fiber optic temperature measurement system include:

– Optical fiber: The medium through which light travels
– Light source: Typically a laser or LED
– Detector: Converts optical signals into electrical signals
– Signal processing unit: Analyzes and interprets the data

## Applications Across Industries

The versatility of fiber optic temperature measurement has led to its adoption in numerous fields:

### Industrial Applications

– Power generation and distribution
– Oil and gas exploration
– Chemical processing plants
– Aerospace and automotive manufacturing

### Medical Applications

– Hyperthermia treatment monitoring
– Thermal ablation procedures
– Biomedical research
– Patient temperature monitoring

### Environmental Monitoring

– Geothermal energy systems
– Climate research
– Structural health monitoring
– Fire detection systems

## Advantages Over Traditional Methods

Fiber optic temperature measurement offers several distinct advantages:

– Higher accuracy and precision
– Faster response times
– Greater durability in extreme conditions
– Reduced maintenance requirements
– Enhanced safety in hazardous environments

## Future Developments and Trends

As technology continues to evolve, we can expect to see:

– Miniaturization of sensors for more compact applications
– Integration with IoT and smart systems
– Enhanced data processing capabilities
– Expansion into new industries and applications
– Improved cost-effectiveness for wider adoption

## Conclusion

Fiber optic temperature measurement represents a significant advancement in the field of temperature monitoring. Its unique capabilities and wide-ranging applications make it an indispensable tool in modern industries. As research and development continue, we can anticipate even more innovative uses and improvements in this transformative technology, further solidifying its position as a cornerstone of precise temperature measurement in the 21st century.

# Unlocking the Secrets of Hyperbaric Oxygen Chambers: A Deep Dive into Healing and Recovery

Hyperbaric Oxygen Chambers (HBOT) have long been a subject of fascination and intrigue in the medical world. These chambers, which deliver 100% oxygen at pressures higher than atmospheric levels, are not just a modern marvel but a testament to the power of oxygen in healing and recovery. In this article, we will explore the science behind HBOT, its applications, and the potential it holds for various medical conditions.

## The Science Behind Hyperbaric Oxygen Therapy

At the core of Hyperbaric Oxygen Therapy is the principle that increased oxygen levels in the blood can accelerate the healing process. When a patient enters a hyperbaric oxygen chamber, they are exposed to pure oxygen at pressures typically 1.5 to 3 times higher than normal atmospheric pressure. This high-pressure environment allows the lungs to gather more oxygen than would be possible under normal conditions.

The increased oxygen levels in the blood can have several beneficial effects:

– Enhanced tissue repair: Oxygen is essential for cellular metabolism and the production of ATP, the energy currency of cells. By increasing oxygen availability, HBOT can promote faster tissue repair and regeneration.
– Reduced inflammation: High oxygen levels can help reduce inflammation by modulating the immune response and decreasing the production of pro-inflammatory cytokines.
– Improved infection control: Oxygen is a potent antimicrobial agent. HBOT can enhance the body’s ability to fight infections by increasing the oxygen concentration in tissues, which can inhibit the growth of anaerobic bacteria.

## Applications of Hyperbaric Oxygen Chambers

Hyperbaric Oxygen Therapy has a wide range of applications, from treating chronic wounds to aiding in recovery from traumatic injuries. Here are some of the key areas where HBOT has shown promise:

### Chronic Wound Healing

Chronic wounds, such as diabetic foot ulcers and venous stasis ulcers, can be notoriously difficult to treat. HBOT has been shown to improve wound healing by increasing oxygen delivery to the affected tissues, promoting angiogenesis (the formation of new blood vessels), and enhancing collagen synthesis.

### Radiation Injury

Patients who have undergone radiation therapy for cancer may experience tissue damage as a side effect. HBOT can help mitigate this damage by promoting tissue repair and reducing fibrosis. It is particularly effective in treating radiation-induced necrosis, a condition where tissues die due to the lack of blood supply caused by radiation.

### Carbon Monoxide Poisoning

Carbon monoxide (CO) poisoning is a life-threatening condition that occurs when CO binds to hemoglobin, preventing oxygen from being transported to tissues. HBOT is a critical treatment for CO poisoning, as it rapidly increases the amount of oxygen in the blood, displacing CO and restoring normal oxygen levels.

### Sports Injuries and Recovery

Athletes are increasingly turning to HBOT to accelerate recovery from injuries and improve performance. The therapy can reduce inflammation, promote muscle repair, and enhance overall recovery, allowing athletes to return to their sport more quickly.

## The Future of Hyperbaric Oxygen Therapy

As research into HBOT continues, new applications and benefits are being discovered. Emerging studies suggest that HBOT may have potential in treating neurological conditions such as traumatic brain injury (TBI), stroke, and even neurodegenerative diseases like Alzheimer’s. The ability of HBOT to enhance neuroplasticity and reduce neuroinflammation is particularly exciting.

Moreover, advancements in hyperbaric chamber technology are making the therapy more accessible and comfortable for patients. Portable and home-use hyperbaric chambers are becoming more common, allowing patients to receive treatment in the comfort of their own homes.

## Conclusion

Hyperbaric Oxygen Chambers represent a powerful tool in the realm of medical therapy. By harnessing the healing properties of oxygen under pressure, HBOT offers a non-invasive and effective treatment option for a variety of conditions. As our understanding of this therapy continues to grow, so too does its potential to unlock new avenues of healing and recovery.

Whether you’re a medical professional, a patient, or simply someone interested in the cutting-edge

Xometry has added four new 3D printed metals to its on-demand manufacturing services: maraging steel, Inconel 625, Inconel 718, and titanium. These premium alloys complement the already available stainless steel and aluminum metal 3D printing.

Metal parts in these alloys are produced using direct metal laser sintering (DMLS). This process fuses powdered metal with a high-powered laser to build parts layer by layer. DMLS makes fully dense metal parts with exceptional mechanical properties and less design constraints than traditional manufacturing. Parts can be designed with lattices, generative- or topology-optimized structures, and integrate multiple assembly components into a unified body.

Metal 3D printed parts

DMLS Materials Available Through Xometry

3D Printed Metal Description 3D Printed Metal

Aluminum AlSi10Mg

Description

A lightweight aluminum alloy that is a great alternative to machining or casting complex geometries.

3D Printed Metal

Stainless Steel 17-4

Description

A fully dense 17-4 PH stainless steel metal with a hardness of 40 HRC. This metal is heat treatable.

3D Printed Metal

Stainless Steel 316/L

Description

A fully dense 316L stainless steel metal with superb corrosion resistance. This metal meets the requirements of ASTM F138.

3D Printed Metal

Maraging Steel MS1

Description

A heat-treatable tool steel that can be post-hardened to more than 50 HRC to achieve excellent hardness and strength.

3D Printed Metal

Inconel 625

Description

A heat- and corrosion-resistant nickel alloy offering high oxidation resistance.

3D Printed Metal

Inconel 718

Description

A heat- and corrosion-resistant nickel alloy ideal for high-temperature applications. It offers good tensile, fatigue, creep, and rupture strength at temperatures up to 700 °C (1290 °F).

3D Printed Metal

Titanium Ti64

Description

A lightweight alloy with excellent mechanical properties and corrosion resistance used in high performing engineering applications as well as biomedical devices.

3D Printed Metal

Custom / Other Material

Description

Looking for another material? Choose “custom” and let us know by submitting your quote for a manual review.

3D Printed Metal Description

How to Get a Metal 3D Printing Quote for Inconel, Maraging Steel, and Titanium

Step 1: Upload your 3D model to the Xometry Instant Quoting Engine℠

Step 2: Click “Modify Part” and choose DMLS as the process

Step 3: Select your material and add any features or notes

1. If you choose Inconel, titanium, or maraging steel: You will be prompted to get a manual quote via digital RFQ. Once you are in the Xometry Digital RFQ Marketplace, your RFQ will automatically populate with your instant quote information. You also have the option to add more details about your requirements before submitting the RFQ. Watch How Our Digital RFQ Service Works.
2. If you choose stainless steel and aluminum alloys: You will receive an instant price and lead time.

Want to learn more? Download our DMLS Design Guide and review our capabilities.

Greg PaulsenThey call me the Director of Application Engineering at Xometry. This means I not only get to produce great design-for-manufacturing content but also consult on various custom manufacturing projects using CNC machining, additive manufacturing, sheet metal, urethane casting, and injection molding. If you have a question, I'm your guy.

Read more articles by Greg Paulsen

The manufacturing industry is one of the most dynamic industries in the world. For instance, some decades ago, you could manufacture products or parts using only conventional tools. However, it’s quite challenging today to fabricate any part and meet product designers’ requirements without using special manufacturing processes like angular milling.

The angular milling process isn’t like any other process; its unique mode of operation and cutting tool design make it ideal for fabricating a broad range of complex parts. And in this article, we’ll cover everything you need to know about this fascinating manufacturing method.

What is Angular Milling?

Angular milling (or angle milling) involves removing portions of material from a workpiece to form the desired product. However, unlike conventional milling, angular milling creates flat surfaces that aren’t parallel (or perpendicular) to the axis of the cutting tool. Instead, the surfaces are at an angle to the cutting tool’s rotating axis, as shown below.

Figure 1: The angular milling process

Notice how the angular milling process utilizes a unique cutting tool that features angular grooves. This cutting tool is called the angular (or angle) milling cutter, and it allows machinists to machine angles and features like notches and serrations. However, these cutters come in different types, each with its unique feature and suitability for different application needs.

Types of Angle Milling Cutters

The angle milling cutters are categorized into:

1. Single-angle milling cutters
2. Double-angle milling cutters

Figure 2: Single-angle and double-angle milling cutters

Single-angle Milling Cutter

The single-angle milling cutter features teeth on the cutter’s conical (or angular) face. These cutters come in different types and are specified based on the combined angle between the cutter’s conical face and the larger end face. Common single-angle milling cutter angles include 30°, 45°, and 60°.

The single-angle milling cutter is ideal for creating simple dovetails, slots, and bevelling parts. Top-tier machine shops also rely on the 30° single-angle milling cutter for surface finishing operations.

Learn more: Understanding Surface Finishing in Manufacturing.

Double-angle Milling Cutter

The double-angle milling cutter features V-shaped teeth with two conical faces at an angle to their end faces. This unique design allows machinists to create cuts from either side of the cutter, making them ideal for fabricating v-grooves, serrations, and other angular surfaces, as shown below.

Figure 3: Fabricating v-grooves using the double-angle milling cutter

Machinists also use the double-angle milling cutters for thread milling, chamfering and deburring operations.

Tips for Angular Milling

Here are essential tips that top-tier machine shops adhere to during angular milling:

• Operate angle milling machines at the recommended speed for the type of angle milling cutters used. Excessive speeds will cause the cutting tool to overheat and wear rapidly. Top-tier machinists typically use angle milling cutters made of carbide or steel for high-speed angle milling.
• Choose an angle milling cutter large enough to span the workpiece. This allows machinists to perform cutting operations with a single pass of the cutter across the workpiece.
• Use coarse angle milling cutters during the initial machining stage to create roughing cuts, while fine angle milling cutters are better suited for surface finishing operations.
• Use a combination of milling cutters to create complex cuts and features. For instance, a combination of fly cutters and angle milling cutters might be ideal for milling the square end of a shaft or reamer shank.
• Use computer numerical control (CNC) technology to automate the sequence of movement of the cutting tool and workpiece to create desired products. This technology eliminates the human error factor common in the conventional angle milling process.

Learn more: Understanding How CNC Machining Works.

Angle Milling: Gensun Can Help

Now that you know what the angle milling process entails, you’d agree that it can create complex features. However, your project’s success also depends on the machine shop you work with.

Gensun Precision Machining is a leading provider of machining services across Asia. We have a team of highly qualified machinists and quality control experts who work together to get your product done right.

Learn more about our CNC machining services.

Oct 21/24

Advancements in Smart Technology: How Custom Automotive Parts Are Evolving

 

Imagine driving a car that can learn your preferences and adapt in real-time to enhance your driving experience.

As you accelerate down the highway, sensors adjust the suspension for a smoother ride. Your custom dashboard displays real-time performance data tailored exactly to your needs. This isn’t science fiction. Thanks to advancements in smart technology, it’s today’s reality.

Read on to find out how custom automotive parts can advance through smart technology.

3D Printing and Advanced Materials

With 3D printing, designers can create complex geometries and intricate auto part designs that were previously impossible or too costly using traditional methods. This technology allows for fast prototyping and on-demand production of custom parts, beneficial for car manufacturers or retrofitters looking to create their own designs.

From custom air intakes to intricate dashboard elements, 3D printing enables personalization that aligns with the evolving demands of smart technology in the automotive industry.

If you’re interested in these automotive tech trends, sit down with the experts to start prototyping.

Custom Auto Parts Innovation: Smart Safety Systems

Safety systems are transforming the landscape of custom automotive parts. They prioritize driver and passenger safety through the integration of advanced technologies. These systems go beyond traditional mechanical safety features, incorporating technology that can detect potential hazards and respond in real-time.

These advanced safety features include:

• Sensors
• Cameras
• AI-driven components

This smart technology can also help improve control.

Lane-keeping systems use cameras and sensors embedded in custom mirrors and body panels to monitor lane markers. It can gently steer the car back into the right lane if it starts to drift.

Enhanced Lighting and Visibility

Custom lighting solutions, such as adaptive LED headlights and smart taillights, are becoming essential upgrades for drivers seeking better road illumination and increased safety. Adaptive LED headlights, for example, automatically adjust their brightness and beam pattern based on:

• Driving conditions
• Weather
• Oncoming traffic

Smart lighting systems also allow for extensive customization. Custom headlight designs and LED strips can be programmed to change colors or create unique lighting patterns, allowing drivers to personalize their vehicles.

Smart technology integration means these systems can be controlled via mobile apps, allowing for real-time adjustments and synchronization with other vehicle functions.

Sustainability and Eco-Friendly Customization

As the automotive industry shifts towards greener practices, sustainability, and eco-friendly customization have become key to the future of automotive parts. Smart technology allows for custom part creation that enhances vehicle performance and reduces environmental impact.

Auto part manufacturers are also inventing new and exciting ways to reduce waste. For example, they might use smart inventory management systems.

These systems ensure materials and parts are used before they expire or become obsolete. They track the lifecycle of custom parts and materials, enabling manufacturers to order only what’s necessary and avoid overstocking.

Custom Automotive Parts: Start Today

The world of custom automotive parts is changing now that smart technology is here to stay.

Are you looking for intelligent vehicle components? Mayco International is here for you. We’ve been creating advanced, top-of-the-line products for our clients since 2006.

Contact us to learn more.

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This blog was updated in August 2022, to announce the grand results of RoboSub 2022. AVBotz placed 2nd out of 39 teams in the Autonomy Challenge. We are so proud of the team’s hard work and determination!

Robotic Submarines and DATRON Dynamics: The Story of AVBotz

The future of autonomous underwater vehicles (AUVs) is being shaped by robotics teams like AVBotz at Amador Valley High School, in Pleasanton, California. Founded in 1999, the mission of the AVBotz organization is to introduce students to the wide world of robotics. Each year, students compete at RoboSub, an international robotic submarine competition. RoboSub challenges both collegiate and high teams from around the globe. Their robots are put to the test by completing different tasks like passing through gates, manipulating buoys, identifying colors and shapes, launching projectiles, and more. These tasks are inspired by current research in autonomous underwater systems. The competition theme changes each year in order to push the limits of innovation and imagination from competing students. AVBotz likes to make use of their outstanding engineering skills, so they actually design their AUV from scratch.

AVBotz is recognized as one of the best performing high school teams, with their Barracuda model taking 7th place and ranking the highest scored run at the 2015 competition. However, it’s not just about placing well at RoboSub for the students, they are committed to sharing their knowledge and experience with others. For instance, they have over 35,000 lines of open-source code available on GitHub to promote collaboration between other robotic clubs. The students are very involved with their community, inspiring younger generations to participate in STEM studies and clubs. They’ve taught coding and robotics workshops and even hosted a virtual computer-building workshop. The team members also mentor the robotics club at Harvest Park Middle School.

How It All Started

AVBotz’s partnership with DATRON Dynamics began in 2015. Former team member Brody West, and his peers, found themselves in “deep water” with their new build. It was the team’s first time figuring out the AUV design and how to make it. They had no idea where to find resources and didn’t even have technical advisors yet. Since the robot needed to operate underwater, the parts must be precise, or it’s game over. Given that many of the parts (like end caps and side panels) had to be watertight, they needed a CNC machine for that level of accuracy. So, Brody began researching local CNC machine shops capable of creating the parts they needed for their robotic submarine design. Brody visited machine shops all over town looking for team sponsors but had no luck…until a listing for DATRON Dynamics popped up.

Chris Hopkins, the Director of Technology at DATRON Dynamics, remembers Brody reaching out that year and was eager to help those students out. Chris didn’t just want to make parts and ship them off though. He wanted to help them learn how DATRON technology works, so they would understand how the parts were made. So, Brody and some team members visited the DATRON office in Livermore, California to see the CNC machines in action. Brody remembers his first impression of the DATRON machines, thinking they were clean and sleek. Like “the Apple of CNC machines.”

Gearing Up For RoboSub

While the team prepared for the upcoming competition, Chris provided mentorship for all CNC-related items and became the team’s first (and only) technical advisor. He showed AVBotz how to take a design file and turn it into a finished project. The students designed their parts in CAD/CAM, and Chris reviewed the files and milled the parts on one of the DATRON machines. Brody recalls how ambitious and hard-working his fellow students were during that build. They spent every weekend and every day in the summer working on their robot. Brody remembers when he wasn’t in class, he was working on the autonomous underwater vehicle build.

The team really wanted to win, and their hard work paid off, as their AUV ended up beating out a bunch of universities at RoboSub! That was the last competition for Brody since he graduated from high school and moved on to MIT. After being a part of AVBotz for four years, his experience with the team and the competitions reinforced his desire to join the engineering field.

DATRON Dynamics knows that programs like AVBotz are vital to the future of engineering and manufacturing, and that’s why we are happy to support them. Plus, our team really enjoys working on the autonomous underwater vehicle parts! To this day, Chris and our team continue to support AVBotz and mentor its members. Some of the students stay in touch with Chris and let him know he helped them find their career path. Chris says there is nothing more rewarding than hearing that from a student.