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Each fall and spring semester, students convene at the Main Campus at UTSA with booths, ideas and prototypes. A crowd of judges, local organizations, students, faculty and sponsors walk around and talk to the students about their projects and ask questions. Students get the real-life experience of "pitching" their project with hopes of getting funding or support to move to the next level.

Congratulations to this semester's Tech Symposium winners!

First place: EyeSpy
Second place: BioMedyx
Third place: Muttley Crue

Biomedyx

Device for detecting retinal disease takes top prize in UTSA’s spring Tech Symposium

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Check out all of the photos from the Fall 2024 Symposium

Biomedical Engineering Design II

Soft Tissue Anchor  | Pes planus, or flatfoot, affects approximately 20-30% of the population, with over 3 million cases annually. Currently, corrective procedures focus on rehabilitating the damaged posterior tibial tendon by targeting the flexor digitalis longus (FDL) tendon. This transfer procedure utilizes soft tissue anchor sutures to secure the FDL to the navicular bone. However, these techniques often lead to complications such as anchor pullout and inaccurate suturing. Our goal is to develop a plate-like device that securely fixates the FDL to the navicular bone and other anatomical locations while preserving tissue integrity, thus offering a more reliable and effective surgical approach.

This project is sponsored by Nvision Biomedical Technologies

Prothrombin Time Test Device  | Introducing the CoaguLite a Prothrombin Time Analyzer, a groundbreaking biomedical device that utilizes light refraction technology to redefine coagulation analysis. A small blood droplet, obtained using a lancet, is carefully drawn into an optimum specialized capillary tube. The capillary tube is then inserted into the designated port on the device. Using a laser diode and camera, as the refractive index changes between that of standard blood to that of clotted blood, the device will provide real-time measurements of prothrombin time and international normalized ratio levels. This user-friendly device is critical for adjusting blood-thinner medication dosages effortlessly, accessibly, and precisely.

This project is sponsored by Mrs. Charissa Barnes

Heart Suspension Device to Increase the Viability of Transported Donor Hearts |  Worldwide, the demand for compatible donor organs alarmingly exceeds availability, especially in hearts. To combat this dilemma, organ transport companies including Vascular Perfusion.Solutions have developed ground-breaking devices to preserve and extend the time an organ has to arrive viable. In addition to these factors, managing the mechanical forces experienced by hearts is also of interest. Sudden changes in direction during transport can cause acute strains on blood vessel connection points, which may lead to additional organ swelling and damage. Our device aims to minimize these mechanical risks by providing additional organ support and quantifying the heart’s state through sensors which monitor the fluid temperature, the swelling of the heart as well as the impedance of the tissue.

This project is sponsored by Vascular Perfusion Solutions (VP.S)

Peritoneal Dialysis Catheter for Maintenance of Drainage Flow Rate | Peritoneal dialysis is a vital medical procedure for patients with kidney dysfunction by filtering waste and excess fluid. Approximately 11% of the global dialysis population are patients receiving peritoneal dialysis. In the US, nearly 808,000 people are living with end-stage kidney disease, and the market is projected to reach 6.1 billion USD by 2025. We identified the need for a peritoneal dialysis catheter to minimize drain pain risk, while maintaining stable drainage flow rates without increasing absolute flow. This procedure enhances patients’ independence and overall quality of life while leading a more normal life.

Mechanical Intraoperative Ultrasound Stabilization Apparatus | In many surgical fields, like vascular and interventional radiology, intraoperative ultrasound systems are utilized to guide the operation. This process requires the surgeon to simultaneously handle the ultrasound probe and perform the surgery. Current alternatives involve technician intervention through continuous manual adjustment, which introduces significant costs and can be ineffective. Otomo Biotechnologies' solution is a mechanical apparatus designed to securely hold intraoperative ultrasound probes during surgical procedures. This provides a cost-effective, user-friendly solution that enables surgeons to operate with both hands at a stable pressure on patients, and offers versatile base attachment to various ultrasound machines or the patient's bed.

This project is sponsored by Dr. Jorge Lopera

SafeAnchor Fixation System for Urinary and Biliary Drains | The SafeAnchor fixation system is designed to be an improvement upon current fixation devices for percutaneous drainage catheters. It may be applied to individuals experiencing urinary retention, bile duct blockage, or liver and kidney-related disorders often require prolonged catheterization. Current percutaneous drainage systems require external tube fixation to the body, with existing stabilization devices posing issues such as infection, catheter dislodgement, patient discomfort, and cumbersome designs. To address these concerns, VitalSolutions Engineering has developed a device for biliary and urinary drains which aids in catheter fixation and aims to improve upon the functionalities and mechanisms of existing devices.

This project is sponsored by Jorge Lopera

Superior Vena Cava Blood Filter for Pulmonary Embolism Prevention | In individuals with upper extremity venous thrombosis, the risk of pulmonary embolisms (PE) is elevated, especially for those with contraindications for systemic anticoagulation. According to the CDC, PE affects 900,000 Americans annually with a growing incidence in the upper extremities. This creates a demand for an implantable blood filter device positioned within the superior vena cava (SVC). Existing filters are made specifically for the Inferior Vena Cava (IVC), however, issues related to mechanical reliability, migration, and venous wall puncture are encountered. Additionally, they cause further complications when utilized in the Superior Vena Cava (SVC) due to the anatomical differences. The proposed device aims to overcome these challenges through an integrated meshing property and a unique structural design required for the anatomically different superior vena cava.

This project is sponsored by UT Health School of Medicine, Department of Radiology

Low-Profile PEG/G Tube Conversion System | Percutaneous Endoscopic Gastrostomy/Gastrojejunostomy (PEG/G) tubes provide enteral feeding to patients unable to ingest sustenance orally, facilitating direct access to the stomach for long-term nutritional support. Currently, patients with standard PEG/G tubes encounter complications: buried bumper, jejunostomy burns, leakages, and dislodgement. Patients often seek to replace standard PEG/G tubes with low-profile systems; however, this procedure is costly and invasive. There is a need to convert from a standard PEG/G tube into a low-profile, low-cost system where patient comfort is prioritized and maintained. The team’s approach includes creating a minimalist feeding tube adapter system with low-cost, flexible, and durable material.

This project is sponsored by Dr. Jorge Lopera

RetinaSpy: A Device to Diagnose Diabetic Retinopathy using A.I. Image Recognition | Diabetic Retinopathy is a noninflammatory disease of the retina, involving blood vessel damage in the light sensitive tissue influenced by diabetes. In San Antonio, approximately 12.3% of the population is diagnosed with diabetes mellitus. Of those that possess type I or type II diabetes, 26% develop diabetic retinopathy and experience vision complications1. The standard diagnostic procedure involves an optometrist or ophthalmologist directly viewing and analyzing the vasculature of the retina through an ophthalmoscope. Our goal is to develop a fast, cost-effective, and accessible diagnostic device to screen for diabetic retinopathy for primary and community health care centers. The device takes advantage of artificial intelligence processing, thereby providing an examination without the presence of an eye specialist and expanding the possibilities of detecting various other ocular disorders in the future.

This project is sponsored by Mr. Polo del Barrio

AED Integration System | The need for a universal drone delivery system for Automated External Defibrillators (AEDs) is developed from the time-sensitivity of cardiac arrest situations. Current AEDs are not always available in all locations, especially in rural or remote areas, where response times are often hindered. Hence, the development of a simple kit to equip common drone types with AEDs aims to provide rapid and life-saving access to AEDs in hard-to-reach locations, ultimately increasing the chances of saving lives in cardiac emergencies. Thus, identifiable problem is the limited availability of Automated External Defibrillators (AEDs) in remote or inaccessible locations, posing a critical challenge in delivering timely life-saving interventions during cardiac emergencies.

This project is sponsored by Dr.Hood

Portable Ruggedized Digital Urinometer to Enhance Burn Resuscitation for Combat Casualty Care | In modern combats, 1 in 4 injuries is burn-related, with future battlefields indicating a heightened risk. Monitoring urine output (UO) is crucial for fluid resuscitation in burn patients. UO serves as a reliable indicator for fluid management, aiding survival. However, existing solutions aren't suited for battlefield conditions. 2XTech's portable digital urinometer addresses this gap. It enables real-time UO tracking in life-threatening trauma cases, enhancing battlefield medicine. This innovation promises improved survival rates among combat casualties by ensuring effective fluid resuscitation. With its deployment, combat medics can better manage fluid levels, crucial for patient care in the acute burn phase, marking a significant advancement in combat casualty care.

This project is sponsored by U.S. Army Institute of Surgical Research

ATPeek Electro-Sensor | There is a pressing need for individuals to monitor their oral health between dental visits. As with most chronic diseases, early detection is vital in the prevention of permanent damage. The proposed design aims to provide a risk assessment of dental caries for at-home use. The process of use is easy to follow, and the numerical results are simplified to a risk scale. This device will serve as a diagnostic tool for users to evaluate their oral health, more specifically for cariogenic bacteria.

Chemical Engineering Design II

Combatting Greenhouse Gases through Chemical Conversion | To convert a flue gas stream containing carbon dioxide, it is necessary to develop an economically feasible and theoretically sound engineering design. This project proves the viability of converting carbon dioxide to dimethyl ether through a proposed plant design substantiated by an ASPEN HYSYS simulation, a 30 year economic analysis, and a comprehensive plant management system.

E-Methanol production from recycled GHG to reduce their emissions | This project presents a pioneering method for methanol production by integrating the electrolysis of water with the utilization of recycled carbon dioxide (CO₂). Water electrolysis provides the necessary hydrogen, while captured CO₂ serves as the carbon source for methanol synthesis, drastically minimizing greenhouse gas emissions. Powered by renewable energy sources, this combined approach not only counteracts the environmental drawbacks of traditional methanol production but also offers a pathway to diminish rising atmospheric CO₂ concentrations.

CO2 Capture for DME Synthesis | CO2 is a harmful greenhouse gas that is constantly being emitted into the environment as waste from chemical processes.  In the ZGM refinery, a significant amount of CO2 is produced in the combustion of methane gas, which is not able to be vented due to Environmental Protection Agency regulations.  Therefore, this research will focus on decreasing CO2 from a chemical plant by means of using the CO2 to create a chemical for profit.  Through feasibility analysis, the particular chemical chosen to be produced is dimethyl ether.

Synthesis of Methanol from CO2 Capture | The synthesis of methanol from CO2 capture is a promising technology driven by environmental, economic, and social motivations, addressing climate change, waste reduction, and circular economy promotion. Methanol serves as a sustainable fuel and valuable chemical precursor, aligning with the increasing global demand for responsible sources. This project aims to deliver industrial-scale high-purity methanol by converting flue CO2 with 0.84 conversion efficiency, targeting around 0.8 product purity, all simulated using Aspen. Design| constraints focus on economic, environmental, social, and health considerations, strategically positioning itself in the evolving methanol industry while maximizing conversion efficiency and product purity.

Project Ether: Sustainable Dimethyl Ether Synthesis from Flue Gas  | Greenhouse gas emissions have come about as a primary result of human activities and natural processes. Reducing greenhouse gas emissions is crucial to mitigating negative impacts and slowing the rate of global warming and climate change. The design project explores CO2 sequestration via conversion to dimethyl ether (DME). DME was chosen as the specialty chemical produced primarily from CO2 in this design project based on the comprehensive economic assessment of the markets for DME, ethylene, propylene, hydrogen, and any other products of significant economic value.  DME serves as a clean-burning fuel and chemical feedstock, offering energy density, clean combustion, and compatibility with existing infrastructure. The CO2 is sourced from flue gas generated from a methane gas heater. The design places particular emphasis on the bi-reforming pathway for carbon capture, given the production of methanol and H2 as byproducts and targeted H2/CO ratio. Ongoing research are vital for optimizing this technology and addressing greenhouse gas emissions on a larger scale.

CO2 to DMC | As the world has continued to grow, the greenhouse gas production has continued to grow with it. Transportation, industry, commercial, residential, and electricity generation are different sectors of civilization that heavily rely on the use of chemicals that produce greenhouse gases. Through time, the impact on the environment has been severe and the production of greenhouse gases has shown no signs of slowing down. L.A.N.D. Renewable Resources has taken the responsibility of utilizing the greenhouse gases to minimize the environmental impact and create products that serve a cleaner purpose. L.A.N.D. Renewable Resources will capture greenhouse gases and produce DMC for lithium-ion battery manufacturing, biodiesel production, and as a fuel additive. This green reagent production design will be centered around maximizing efficiency in unit operations and minimizing waste through our closed loop system. This allows the design plant to keep environment impact low, sustainability high, and profitable. 

Optimizing CO2 Removal from Flue Gas: Aspen HYSYS Simulation of Absorption Tower for Methanol Synthesis​ | In the face of escalating environmental challenges, the need for innovative solutions to address carbon dioxide (CO2) emissions has never been more urgent. Historically considered a primary contributor to climate change, CO2 emissions are now being viewed through a new lens—one that sees them not just as a problem to be mitigated, but as a resource that can be harnessed for the betterment of our planet.​

This comprehensive review delves into identifying economically optimal chemical products utilizing carbon dioxide (CO2) as the primary feedstock. The proposed process incorporates series of chemical reactions for converting CO2 into methanol, with dedicated sections for feed and final product purification.​

The design of the plant places a strong emphasis on environmental considerations, underscoring a dedicated commitment to sustainability. A crucial aspect involves striking a balance between economic justification and energy consumption, with a specific emphasis on minimizing energy usage. Furthermore, the plant design prioritizes simplicity and safety, strictly adhering to established Health, Safety, and Environment (HSE) guidelines.​

The narrative concludes by highlighting enduring challenges yet to be addressed in the realm of synthesizing methanol from CO2. Additionally, it delves into future perspectives aimed at shaping an energy vision that is not only resilient but also in harmony with the demands of environmental sustainability.​

CME Plant Design | The senior design project aims to develop a sustainable chemical plant converting dimethyl ether (DME) back into carbon dioxide (CO2), offering insights into carbon cycle management. Leveraging innovative methodologies, the plant's design will reverse DME production processes, including methanol dehydration and CO2 hydrogenation. Priority is given to efficiency and environmental impact, integrating CO2 capture technologies for recycling or storage. This project addresses global carbon emissions by showcasing a feasible pathway for closing the carbon loop in chemical production, contributing to a more sustainable future [1]. Additionally, insights from relevant studies on DME production from CO2 and CO2 utilization technologies will inform the project's methodology and design approach.

Carbon Capture  | This project presents a detailed explanation of the process involved in transforming flue gas and hydrogen into dimethyl ether through a series of procedures. It outlines the various steps undertaken from intake to production, offering insights into the complex chemical and engineering processes involved. By delving into each stage, this project aims to provide a comprehensive understanding of the production of dimethyl ether from flue gas and hydrogen.

Civil Engineering Design II

Chapters & Chill | Design of a bookstore with integrated lounge seating as an addition to The Vance Jackson Park. The project will focus on creating a structure that fits into the park environment and serve the surrounding community. Key considerations include sustainability, safety standards, and a layout featuring bookshelves, snacks bar and lounge spaces. Site development will prioritize accessibility, design and construction.

Felicita's Eatery | At Meskal Engineering, our mission empowers clients to realize sustainable visions while promoting San Antonio’s growth with community-centric engineering. Our current project, Felicita’s Eatery encompasses this vision. Felicita’s Eatery is a restaurant located on the East Side of San Antonio with an outside balcony and patio. The proposed restaurant focuses on providing the local community with delicious farm-to-table food with a variety of vegetarian options. Two cisterns will mitigate drainage and provide water to the restaurant’s landscape as an acting sustainability feature. Additional Low Impact Development and landscaping features will provide customers with a refreshing restaurant experience.

SA Soccer City | SA Soccer City is a comprehensive civil engineering design initiative undertaken by senior students at UTSA as part of their Senior Design II course. The project's focal point is the design of a central field house, which will serve as the primary structure within the athletic complex. This complex also features four regulation-size soccer fields with an accompanying parking area. A key aspect of the project is the innovative use of recycled water, sourced from the SAWS purple pipe system, for irrigation purposes. The project encompasses many civil engineering disciplines, including geotechnical, water resources, transportation, utilities, and structural engineering.

Southeastern Gateway Ph.1 | The Southeastern Gateway Phase I project at the University of Texas at San Antonio (UTSA) aims to enhance the southeastern edge of the campus in alignment with UTSA's 10-Year Vision. This transformative initiative includes:

 

  1. Repurposing Bauerle Rd. Lot 1 to accommodate a significant campus addition, fostering student well-being and community engagement.
  2. Constructing Fiesta Hall, a four-story residential facility with modern amenities and a fourth-floor terrace named Rowdy Rooftop, serving as a vibrant hub for campus life, supporting student living and collaborative interaction.
  3. Proposal for the construction of a roundabout at the intersection of James Bauerle Road and East Campus Dr to improve traffic circulation and enhance safety within the campus vicinity.
  4. Implementation of comprehensive civil engineering tasks, including site grading, drainage design, and utility coordination, ensuring compliance with safety and environmental regulations.

 

This reflects UTSA's commitment to excellence, innovation, and fostering a dynamic, sustainable campus environment conducive to student success and community involvement.

Local Flavors Market | BMG Engineers is a diverse team that is exposed to new perspectives and ideas. We provide safety, integrity, quality, innovation, accountability, and teamwork. The grocery store, Local Flavors Market is planned to be constructed in the Thunder Hills community of San Antonio, TX. Local Flavors Market will be a one-story 20,000 sq-ft building providing groceries and food sourced locally. Our plan is to deliver an exceptional facility that caters to the customers’ needs while aligning with our organization’s core values.

The L Equestrian Center  | The L Equestrian Center is an project designed by AGC engineers, prioritizing equine comfort and safety. With a 20-stall barn, integrated office, and modern living quarters, it offers luxury for both horses and humans. Advanced features such as self-watering systems, ventilation, and grooming areas ensure optimal care. A covered 120’x60’ arena and round pen provide high-quality training facilities. Dedicated storage and a cistern streamline daily operations. Complemented by an outdoor riding arena, roads, and parking, it demonstrates AGC engineers' technical expertise. This facility epitomizes excellence in equestrian engineering and design, encapsulating luxury, and functionality.

Rinse and Roll Carwash | Civil design plans for a carwash located near 1604 and Blanco. Plans include a civil set, drainage, floodplain analysis, structural, environmental, and foundation designs.

Electrical & Computer Engineering Design 1

Hands-Free Dental Loupe with Spectrally-Tunable Light Phase II | This project aims to develop a hands-free dental loupe with a spectrally tunable light system. By integrating adjustable LEDs and a smartphone app interface to control the light frequencies, dentists can easily customize light intensity, color to match tooth shade, and highlight dental fillings. This enhances accuracy and efficiency while minimizing the risk of premature curing and cross-contamination during dental procedures. The design process involves analyzing phase 1 (completed Fall 2023), selecting improved LED technologies, hands-free color mode selection, lenses, housings, and battery systems, while ensuring compliance with regulatory standards and optimizing for comfort and usability.

This project is sponsored by Rancho El Toston

The Texas Tag & Title Vehicle Registration Overhaul | The Texas Tag & Title Vehicle Registration Overhaul project overhauls the vehicle registration and title process for Texas residents and visitors. This innovative project seeks to improve time efficiency and data security. Users will be able to upload documents using the new portal from the comfort of their own home or using a local kiosk location. When using the document uploader on the new portal, user information is reviewed using AI image processing software which allows for real time feedback. All verified and approved personnel data is then stored in a secured database. Once the process is completed, consumers can conveniently print their registration renewal stickers or title documents at a local Texas Tag & Title kiosk location.

This project is sponsored by Texas Tag and Title

Personal Items and Devices UV Disinfector | We are designing a compact 360-degree disinfection box using ultraviolet sterilization in order to address the importance of sanitizing items like cell phones, cash, keys, paperwork, and other objects that may be difficult to clean with traditional methods like sanitizers.

UV-C light has indeed been proven effective in killing a wide range of viruses, including SARS-CoV-2, within seconds of exposure. Implementing UV-C technology in a compact disinfection box could provide a convenient and efficient way to sanitize everyday items without the need for chemicals or recurring costs associated with sanitizer usage.

AI Wearable Communicator | The AI Wearable Communicator (AIWC) is a compact device that translates foreign languages into the user's desired language. Developed by Team Stealth, it aids communication across languages using Wi-Fi and Bluetooth-capable microcontrollers. Equipped with a speaker, microphone, and camera, it removes language barriers in travel, business meetings, and other situations. Operating through an API interface, the device facilitates seamless communication, enhancing accessibility for users of all backgrounds. The AIWC provides its user confidence by lowering the stress that comes from communicating in a foreign world.

This project is sponsored by Emmanuel Oluga, Co-founder/CEO of AETTHER

SAD Light Therapy Phone Case with Phone App / SADCA | The SADCA uses a revolutionary Light Emitting Therapy Phone Case to combat Seasonal Affective Disorder (SAD). Through a companion app, the SADCA seamlessly integrates light therapy into the users' daily routines by the replication of the sun’s effects. Ultimately, this innovative solution seeks to improve the quality of life for SAD individuals while addressing broader challenges of treatment accessibility and mental health awareness in regions with limited sunlight. The device also offers customizable treatment options to alleviate SAD symptoms. Target consumers for this SADCA include personnel from the education, healthcare, and wellness sectors, who are more susceptible to procuring SAD.

This project is sponsored by Lyle Hood

Lab Sign-In System | The Lab Sign-In System (LSIS) streamlines student access to laboratory spaces by using their student ID for checking in and out during lab sessions. Upon sign-in, students are directed to vacant lab stations to conduct their exercises. Each station is equipped with an interactive sign device allowing students to signal instructors or TAs regarding their needs using a switch that activates a light. The light features three modes: green for station availability, blue for verification needed, and red for lab-related questions. LSIS enhances lab management by automating sign-in processes and facilitating communication between students and instructors.

This project is sponsored by Johnathan Votion

Autonomous Intelligent Drone (AID) | The Autonomous Intelligent Drone (AID) project (in collaboration with the Unmanned Systems Lab) is a continuation of a previous project that is aimed at constructing a cost-effective, multipurpose drone. The AID project tackles modern drone issues by presenting an all-in-one solution that provides both simplified and advanced access to controls. The project will consist of two parts. First, the previous iterations of the project are redesigned for optimization using new hardware components and modifications to the physical body. The second part of the project focuses on developing a conceptual, autonomous flight algorithm.

This project is sponsored by Unmanned Systems Lab (Yongcan Cao)

Extracorporeal Membrane Oxygenation (ECMO) | Venoviva is a wireless control system for ECMO simulation mannequins, elevating the realism of medical staff training. This involves creating a lifelike blood flow system within a cannulation mannequin and developing an iOS app to manage up to five preset failure simulations. This comprehensive solution enables instructors to replicate authentic hospital scenarios, allowing medical staff to apply their skills effectively. By testing these skills in simulated environments, Venoviva aims to enhance patient outcomes through better-prepared healthcare professionals.

This project is sponsored by The Institute for Extracorporeal Life Support

Smart VR GLove | The Smart VR Glove is an affordable innovation in virtual reality technology that offers users an immersive and realistic experience across standard VR systems. It utilizes a novel electromagnetic braking system and haptic actuators to provide precise tactile feedback, simulating the sensation of touch and grasp in the virtual world. Enhanced by AI-driven software, the flex-sensitive resistors offer superior finger-tracking accuracy. This wireless, rechargeable battery-powered glove is designed to provide VR users with a more natural VR experience, setting a new benchmark for affordability, compatibility, and interactivity in virtual environments.

Genisys Guard | GENeral Immobilizer SYStem (Genisys)Guard is an external fail-safe system engineered to terminate Malfunctioning Unmanned Systems (MUS) and provide tracking capabilities to facilitate recovery operations. Sponsored by SwRI Applied Power Division, Genisys Guard is a solution that can be implemented to a variety of MUS to mitigate risk caused by potential malfunctions. Genisys Guard allows for manual termination via a mobile remote featuring a shutoff button and user display, or automatic shutdown through predefined parameters such as signal loss. Following termination, Genisys Guard transitions to recovery mode, sending GPS coordinates to the base station and enabling local tracking via Bluetooth.

This project is sponsored by Southwest Research Institute

Electrical & Computer Engineering Design II

Autonomous Mechanical Tourniquet | Working in conjunction with the Army Institute of Surgical Research, team No Pressure has designed the Autonomous Mechanical Tourniquet (AMT) to revolutionize emergency care by automatically stopping bleeding in critical situations. Traditional tourniquets often fail due to improper use or overtightening, leading to complications. The AMT, equipped with a microcontroller, motorized mechanisms, real-time blood pressure sensors, and a software feedback loop intelligently adjusts applied pressure to stop bleeding without causing nerve damage or allowing unnoticed re-bleeding. This smart tourniquet promises quicker, safer, and more efficient hemorrhage control, improving outcomes in emergencies.

This project is sponsored by United States Army Institute of Surgical Research (USAISR)

Acoustic Material Manipulator | The Acoustic Material Manipulator (AMM) uses acoustic vibrations to levitate and move objects. Using an array of ultrasonic transducers, the AMM will demonstrate a small portion of the potential of acoustic levitation. The future of this device lies in the field of PCB IC population. The lack of moving parts and the ability to pick up and move multiple objects at once will be the largest factors in outperforming the current technologies in use.

This project is sponsored by Rodrigo Martinez

ArteryMark | The ArteryMark Dev team is developing an arterial plaque characterization tool titled ArteryMark. This tool allows researchers to develop a database of annotated artery CT scans for use in training an AI model for autonomous feature recognition. Through ArteryMark’s GUI, researchers import CT scans as images, perform several basic automatic transformations, including edge detection and conversion to a radial coordinate system. Then, researchers manually adjust detected borders, create specific feature regions, and finally export the image as a feature map.

This project is sponsored by Clayton Foundation

Portable Ruggedized Fluid Pump | The Portable Ruggedized Fluid Pump (PRFP) is a cutting-edge medical device designed for critical applications in battlefield and pre-hospital care. Integrating peristaltic pumps, an ESP32 microcontroller, and a touchscreen display, the PRFP delivers precise fluid volumes at adjustable rates, catering to military healthcare providers, medics, and first responders. With a focus on reliability, user-friendliness, and ruggedized design, the PRFP addresses the need for a portable solution in challenging medical environments, aiming to enhance patient care and improve medical response efficiency.

This project is sponsored by U.S. Army Institute of Surgical Research

HEPA Filter Monitoring System | The HEPA filter monitoring system operates seamlessly through a sensor governed by a PLC, gauging the differential air pressure within the filtration setup. When the pressure deviates from the specified range, signifying a saturated filter, the system promptly transmits this data to the human machine interface (HMI), triggering an alert for the user. This proactive mechanism guarantees that users are promptly notified of necessary filter replacements, optimizing air quality and prolonging the effectiveness of the filtration system in any setting.

This project is sponsored by Jim Lussier

PTGO | The Photo Tracking Garage Opener (PTGO) project seeks to revolutionize garage door operations by implementing a highly sophisticated image recognition algorithm. This technology accurately detects and tracks vehicles approaching or leaving the garage. By harnessing advanced camera systems, object detection, and user recognition, PTGO aims to streamline garage door processes while ensuring safety and efficiency. Additionally, PTGO offers automated vehicle detection to distinguish between authorized users and potential intruders or wildlife, thereby providing a secure and intelligent solution for comprehensive garage access management. Through seamless integration with smart home systems, PTGO enhances convenience and reliability for users.

This project is sponsored by Rodrigo Martinez

Portable Pneumatic Tourniquet (Pneumatrix) | Partnering with USAISR, our team aims to develop an automated pneumatic tourniquet to improve survival rates for trauma patients suffering from severe extremity bleeding. Pressure sensors within the device will detect hemorrhaging through blood pressure changes and automatically inflate a compact cuff to stop arterial flow. A self-tightening algorithm allows the tourniquet to apply calibrated, consistent pressures reducing tissue damage around the extremity. Our prototype will integrate the sensors, algorithm, and pneumatic system powered by a 24-hour battery with an efficient controller. This portable device promises to advance hemorrhage management capabilities for secondary medical care, ultimately saving lives.

This project is sponsored by United States Army Institute of Surgical Research (USAISR)

CivicCapture | CivicCapture is ideal for personal safety during solo or outdoor activities, utilizing a

printed circuit board and camera module for dependable video capture. Thereby, acting as credible evidence for personal protection, false accusations, or legal disputes. With a user-friendly design, the device features a detachable clip-on attachment, rechargeable battery for sustained use, and external video storage capabilities. This combination provides a reliable, user-friendly solution for enhanced safety and security through video documentation across various scenarios. Through thoughtful design, this device supports private citizens with reliable documentation when needed most.

Mr. Ohm Educational Robot | The Mr. Ohm project is an educational robot initiative under the BetterBots program, designed to assist teaching coding concepts to high school students. Our team, Triple-B, is focusing on optimizing the triode mixer circuit integral to Mr. Ohm’s LIDAR sensor. The triode mixer outputs a signal at a lower frequency that allows for accurate distance measurements. Triple-B aims to significantly enhance the conversion gain, thereby amplifying the strength of the output signal derived from the two input signals. To achieve this, advanced simulation tools including LTSpice and Easyeda-(PCB) will be deployed for refining the existing circuitry. Subsequently, rigorous hardware testing of these improvements will be conducted.

This project is sponsored by BetterBots

uTurbine | In response to the global energy demand, GustBusters, Wind Runners, and HatchTank have jointly developed a Vertical Axis Wind Turbine (VAWT) specifically tailored to compete in the Department of Energy (DOE) Collegiate Wind Competition (CWC). Our team is tasked with designing, testing, and constructing all the power electronics for the VAWT turbine. The team's design aims to achieve four main objectives: filtering out power oscillations, enabling seamless switching between internal power (generated from the turbine) and external power (a battery), implementing a Data Acquisition (DAQ) system to collect, process, and analyze sensor data, and integrating a user interface (UI).

This project is sponsored by Hatch Tank

HEB Bulk Tank Monitoring System  | This senior design project endeavors to revolutionize the operational efficiency of HEB's dairy plant through the development of an automated fluid leveling system. Currently, the plant's system relies on manual operation, presenting challenges related to overflow management. Our proposed solution integrates cutting-edge sensors and a sophisticated programmable logic controller. This integration not only provides real-time data visualization but also ensures precise control of chemical tank levels. The system orchestrates seamless communication with diverse controls responsible for managing chemical flow, thus optimizing productivity and averting operational disruptions. Ultimately, this innovation showcases a pivotal advancement in enhancing the fluid management processes within the dairy industry.

This project is sponsored by HEB

Rapid Aerial Patrol and Tactical Object Retrieval (R.A.P.T.O.R) | The R.A.P.T.O.R. (Rapid Aerial Patrol and Tactical Object Retrieval) project pioneers an autonomous waterproof object detection system, crucial for astronaut rescue missions after re-entry. Combining a fixed GoPro camera for ground imagery with a drone for aerial reconnaissance, the system covers a maximum range of 175 feet. Employing YOLO and OpenCV technologies, supplemented by the SAHI model in Python, enhances object detection precision. This comprehensive approach enables the identification of vital objects such as life jackets and rafts, facilitating swift and effective rescue operations in challenging environments, ultimately contributing to the safety and well-being of astronauts during post-re-entry scenarios.

Hexapod Robot | The Hexapod Robot will help promote advanced robotics in education for all grades and ages, offering a hands-on learning experience. With a modular design and features like computer vision, LiDAR mapping, and autonomous movement, it inspires creativity and innovation. Users explore robotics concepts through interactive experimentation, learning problem-solving skills and understanding of STEM related topics. This educational tool caters to learners of all ages and groups, igniting a passion for technology and paving the way for a future in robotics and AI.

EPICS

Trash-bot Project | The trash-bot has been an ongoing project within

the EPICS (engineering projects in community service) program at

the University of Texas at San Antonio. As the course name suggests,

the goal is to build a functioning prototype in order to better the

environment starting with the community around us by having

functions like sorting/picking up trash, distinguishing between

objects and obstacles as well as roam around capabilities. The

project consists of building the robot with a separate robot arm

system, camera/sensors, and navigation components operating

under RC (remote control). This semester the project design has

implemented the NASA Rocker design in hopes of building a more

stable, capable, and flexible trash-bot.

This project is sponsored by Saadet Beeson

Mechanical Engineering Design I

Improvement of a Brisket Shredder | The project proposed by H-E-B Fresh Plant is to improve and redesign a newly obtained used shredder machine that they hope can process and shred brisket faster and more efficiently than the machine that is currently been used, while maintaining safety. Currently, they are using a slicer that is time-consuming, requires manual labor, and wastes pounds of product every day. To achieve this, Group PASS will evaluate the newly obtained brisket shredder machine to point possible areas that require major safety improvements, find the causes for the amounts of waste and modified the shredding system to achieve the expected results.

This project is sponsored by HEB Fresh Plant

Automatic Tourniquet | This project aims to collaborate with the United States Army Institute of Surgical Research to develop a prototype device for automating the application of windlass-style tourniquets, addressing challenges in consistency and device stability. The focus is on enhancing the deployment of tourniquets, crucial for halting hemorrhage and reducing injury mortality. The proposed solution involves a self-tightening algorithm, utilizing a mechanism controlled by a pressure sensor. Unlike pneumatic alternatives prone to puncture, this project aims to adapt the automation for windlass-style tourniquets or similar strap-style designs without air bladders. The objective is to identify a mechanism and explore potential sensor inputs for automation, while enhancing the effectiveness and reliability of tourniquet application. 

This project is sponsored by U.S. Army Institute of Surgical Research (Dr. Eric Snider)

C-17 Stacker | To address concerns about the C-17's ability to carry people and cargo, our team is developing the C-17 Stacker with Knight Aerospace. The C-17 is a large cargo aircraft commonly used in the transportation of oversized products. However, on occasion, the C-17 has been used to transport people for evacuations or rapid mobilizations of military personnel. To optimize the mission functionality of C-17s, our project will take advantage of the overhead dead space commonly available during the transportation of cargo by using an elevated pallet system that will roughly double the amount of personnel that can be transported.

This project is sponsored by Knight Aerospace

Heat Resilient Surveillance System  | Heat-Safe Engineering is commissioned to engineer an advanced second-generation modular camera housing assembly. This unit is designed for high-temperature applications, including combustion chambers, reactors, incinerators, and furnaces. The objective is to augment SwRI's capability to provide clients with a vivid, real-time visual inspection of furnace interiors, thereby enhancing data presentation with superior visual interpretation. As the project advances into its second phase, advanced cooling methodologies, including hydrodynamic and pneumatic systems, will be evaluated and integrated to counteract extreme thermal environments.

This project is sponsored by Southwest Research Institute

Automated Rotating Caster | Team ARC is tasked with developing a working prototype of an Auto-Rotating Cast that incorporate a remote-control system to be operated from a distance, a stirring mechanism for separation of impurities from the pure liquid metal, and a drain pour system to eliminate contaminations to get pour into the casting mold. This project, under the mentor and supervision of Dr. Axler, will innovate the casting industry by cutting down the number of injuries in metal casting work and creating an efficient method of self-pouring.

This project is sponsored by Dr. Keith Axler

Automated Chicken Flipper Device | The purpose of this project is to redesign HEB’s current chicken seasoner to facilitate a quality seasoning job while optimizing its functionality across various sectors. This involves minimizing as much waste—including time, energy, seasoning, maintenance and changeover costs, footprint, and potentially other resources—as possible.  To fulfill this objective, a unique approach will be taken in the design by implementing an automated flipping mechanism that solves the primary problem of inconsistent seasoning while meeting all of the client's requirements.

This project is sponsored by HEB

Industrial 3D Materials Dry Cabinet  | The 3D printing industry has a major combatant with filament material dealing with humidity. Now, that being the challenge when scaled up, with multiple spools of filament versus a single filament spool the obstacles becomes greater.  The Industrial 3D Materials Dry Cabinet gives purpose of alteration to storing 3D filament, resin, and how it is maintained. The purpose of the dry cabinet is to increase storage capacity, create an intelligent desiccant air loop, increase efficiency, and have an intuitive controller formatting system. This project will have an innovative design outlook when compared to industry at a fraction of the cost.

This project is sponsored by Navistar

Automated Liquid Loading with Intelligent Execution | With numerous patient-specific dosages ordered on a daily basis, the demand for readily available pre-filled oral syringes can be a challenge for hospital personnel. Traditional methods of filling oral syringes require an extensive amount of effort from pharmacy technicians. This can be attributed to the need for precision in medical dosages, time expended documenting prepared syringes, and effort spent organizing groups of prefills. ALLIE, denoted as Autonomous Liquid Loading with Intelligent Execution, meets these demands through implementation of validation systems that ensure precise doses, thorough documentation of completed oral syringes, and organization of prefills with a batching system.

This project is sponsored by Print and Click LLC

Project G.A.U.R.D.N.E.R. | Team G.A.U.R.D.N.E.R.

A task team under senior design 1 has been assigned to design a mobile and effective aerial vegetation distribution system. The intent is to use techniques in precision aerial distribution to better re-forest remote and inhospitable locations. The task team assignment may be later extended to better develop the device into a viable and profitable product. This could form a new evolution in environmental conservationism and peaceful use of military technologies.

Lightweight Lunar Vehicle | The proposed student project aims to create a light-weight lunar spacecraft capable of operating at the client's requested performance while minimizing superfluous bulk. Sensors must also be installed to provide adequate performance data for motor tuning. To do this, rover platforms will be designed and analyzed to sustain the lunar vehicle while safeguarding sensitive electronics from simulated regolith. The most prominent solution will prioritize performance and mass efficiency while also being cost effective when selecting base materials, being maneuverable for zero radius turns, durable enough to ensure the safety of the motors and sensors, providing adequate driving force to maximize payload relocation, and output performance data to aid with simulations.

This project is sponsored by James E. Johnson

Data Recorder System Interface | The Data Recorder System Interface is a project contracted by South West Research Institution (SwRI) to create a desktop simulation that can replicate the different stresses that an airplane will experience in a flight. Using different sensors, an Airforce cadet can input their own flight profile and the desktop will show what the plane is experiencing using thermocouples, pressure transducers, accelerometers, and a strain gage.

This project is sponsored by South West Research Institution

Continental Tire Duplex/Caster | Introducing a bespoke duplex caster engineered specifically for Continental Tire, designed to optimize manufacturing efficiency and product quality. This custom solution integrates readily available components and precision engineering to enhance tire testing processes. With a focus on durability, flexibility, and seamless integration, the duplex caster promises to elevate Continental Tire’s production capabilities to new heights. From increased throughput to improved product consistency, this innovative solution sets a new standard in tire testing technology, ensuring Continental Tire maintains its position as a leader in the industry.

This project is sponsored by Continental Tire the Americas

The Good Shepherd | The Good Shepherd Senior Design team has designed a dual frequency ultrasonic device. This device’s intended purpose is to assist in the herding of livestock such as cattle and sheep through acoustic motivation. The device is powered by a standard ATV lead acid battery and can be mounted onto a standard ATV rifle rack. Dual ultrasonic frequencies have been chosen to create a unique sound for livestock to react to, that is outside the standard hearing range for humans. The group is pursuing IP protection and to present the device for commercialization.

This project is sponsored by Dr. Keith Axler

Mechanical Engineering Design II

DDynamic Compression System for Enhanced Fixation in Canine Tibial Plateau Leveling Osteotomies | he TPLO (Tibial Plateau Leveling Osteotomy) surgery is a prevalent procedure for dogs with torn cranial cruciate ligaments that requires bone realignment through use of an implant, usually a metal plate. The current process and plate results in prolonged recovery for dogs, possible revision surgeries and is time and resource intensive.

This project seeks to revolutionize the TPLO process by introducing an innovative implant made of shape memory material that reduces surgery time, minimizes invasiveness, and provides optimal patient outcomes. Preliminary concept prototypes and data analysis affirms the new method's safety and efficiency.

This project is sponsored by Blaze Biotech, LLC

Navistar's Electrical Cord Braiding Machine | Navistar operates as a company specializing in commercial vehicle manufacturing and currently braids three electrical wires by hand for testing purposes. The goal of the machine is to produce a tight, traditional three-strand braid for three electrical wires connected to a deutsch connector. The goal will be achieved by a 3-D printed PLA braiding gear design and machine housing. The gears will be set into motion by a stepper motor circuit managed by an Arduino board. To ensure uninterrupted operation and consistent performance, the Arduino board will be powered by an outlet of a minimum stable power supply of 120 volts.

This project is sponsored by Navistar

Fluid Warmer | The D.R.I.V.E fluid warmer project is aimed at being a portable emergency usage medical device to assist in revitalizing patients in need of fluids. This project aims to raise the temperature of the transfused fluid to a temperature that is acceptable for human intake. Expected outcomes of this project is to dispense a fluid in the temperature range of 95-97 degrees Fahrenheit which in practice would be dispensed to the patient. The method of heating the fluid will be in the form of radiative heating on the top surface and conductive heating on the bottom to ensure an even temperature distribution.

This project is sponsored by Robert Lyle Hood

J-Series Pressure Regulator Supersession | Our engineering project is focused on improving the assembly process of EControls’ Cobra LPG pressure regulator. By redesigning the primary and secondary stage covers, we enable the use of identical length screws, thereby reducing assembly errors. Additionally, we are developing an electromechanical flow testing fixture to measure the flow characteristics between the Cobra and Model J pressure regulators. This initiative aligns with our sponsor company, Econtrols', objective of replacing the Model J regulator with the Cobra. The flow test fixture data will validate the suitability of the Cobra regulator as a replacement, affirming its operational efficacy.

This project is sponsored by EControls

Motorized Anti-Ballistic Podium System | The M.A.P.S (Motorized Anti-Ballistic Podium System) project innovates public safety by designing a mobile bulletproof podium. Utilizing a sturdy aluminum shell and a 2000-watt brushless DC motor with a dedicated controller, the podium delivers exceptional maneuverability and speed control. Adapted for law enforcement, it boasts a 48V lithium-ion battery and a hybrid wheel system—tracked chassis upfront for stability and swivel wheels at the rear for agility. This system enhances on-site security measures by providing quick, reliable protection that can adapt to changing threats, balancing the demand for safety with the flexibility of movement.

This project is sponsored by ABS

Assembly for Automotive Fire Testing | Currently, the Fire Technology Department at Southwest Research Institute conducts fire tests for automotive vehicles by manually positioning pans filled with ignited fuel under the vehicle parts of interest. This manual procedure exposes testing personnel to a hazardous fire environment. The Assembly for Automotive Fire Testing (AAFT) seeks to improve the safety of these tests by automating the testing procedure and allowing personnel to conduct their tests from a safe distance. The AAFT will be comprised of a motorized winch system that will automatically move the testing pans to their testing positions.

This project is sponsored by Southwest Research Institute - Fire Technology Department

MARV- Makerspace Autonomous Robot Vacuum | In machine shop environments, valuable time is lost due to the cleaning up

debris from the fabrication of parts. To address this, this project introduces

an autonomous shop vacuum to collect debris. By automating this process, a workshop can reduce the time needed for a human to manually collect possibly

hazardous debris.

This project is sponsored by UTSA Makerspace

Lunar Stake Prototype  | The project consists of two self-assembling prototype Lunar Stakes. Each stake must be capable of being handled by an autonomous rover and able to read and report back results on its own. This means it must be lightweight, durable, self-extended, and be inserted deeply enough into regolith (moon dust and rock). This is so accelerometers can read back seismic measurements and report back its findings. Through further understanding of regolith and its capabilities, this technology will hopefully pave the way for construction projects on the moon for future space missions.

This project is sponsored by Sam Ximenes

Trailer Mounted Telescoping Camera Tower | SWRI wanted a method to replace the need to rent man lifts for guardrail crash tests. Two man lifts would be rented, one to raise a camera above the crash, the other to raise a camera operator to set the camera to the proper field of view. This project is to design a transportable and permanent replacement for both of those manlifts.

This project is sponsored by Southwest Research Institute

Vibration Attenuation Device | Our vibration attenuation device has been developed to reduce vibration in piping stubs to lower strain to acceptable levels. It solves vibrational fatigue issues often requiring production downtime and is a quick fix during standard operations. The solution is engineered utilizing passive damping to be versatile, scalable, and user-friendly.

This project is sponsored by Engineering Dynamics Incorporated

Metal-free Microscope Stage | The AFRL Bioeffects Division is seeking a Metal-Free Microscope Stage for precise X, Y, and Z-axis translations. Metal components in traditional microscopy tools cannot be used due to their interference with radio frequency. The AFRL is seeking a stage that can translate minutely in the Z direction. This is achieved by using a plastic shaft with two different Threads Per Inch (TPI) to obtain an effective TPI of 180 to achieve 1µm precision with a 50mm range in the Z direction. Two screws will be used to achieve 4µm precision with a 10mm range for X and Y.

This project is sponsored by Dr. Steelman

Hydraulic Bolt Tensioner and Preload Readout | When tightening factory standard bolts, some larger-scale bolts require large amounts of force to torque them. By implementing a hydraulic bolt tensioner, companies can feasibly tighten bolts more efficiently, safely, and uniformly. This is because hydraulic bolt tensioners achieve torquing by connecting to a bolt where hydraulic oil is then added to supply pressure, thus applying a preload force that elongates the bolt to be tightened. To further increase the accuracy of the tensioner and longevity of the bolt, the design implements a preload readout system to inform the user how much torque is generated, ensuring them that no undesirable slippage or deformations will occur. 

This project is sponsored by The department of Mechanical Engineering at The University of Texas at San Antonio

Miniature Spring Fatigue Tester | This project addresses manufacturing defects in small wire-diameter springs utilized in Sandia National Laboratories mechanisms, prone to fatigue-related failures. Current fatigue testing methods fail to replicate real-world excitation, potentially leading to inaccurate results. Our solution involves developing a fatigue tester capable of mimicking actual use-case conditions while also capable of capturing magnified images of the springs. Integrated with a user-friendly control system and a data acquisition system for pre- and post-testing analysis, the tester ensures product quality assessment alongside fatigue testing, reducing analysis time. Deliverables include a compact, lightweight tester with precise energize and de-energize times, capable of capturing and contrasting time/displacement curves and visual data to evaluate spring performance effectively.

This project is sponsored by Sergio Gonzales

Group Title | Description description description

Log Loading System | Our client is a US Army veteran who uses a sawmill to provide lumber for his homestead and for his community. He currently uses a tractor to transport the logs and place them onto the sawmill, but this process causes fatigue and pain on our client who suffers from hip and spine injuries sustained in the Army. The purpose of the project is to create an ergonomic log loading system which will efficiently load and rotate logs on his sawmill without aggravating the client's existing injuries.

This project is sponsored by Quality of Life Plus

uTurbine | With the rapidly expanding demand for clean and reliable power, exciting new designs and concepts are pivotal in finding more effective ways of meeting this demand. Wind energy is a prominent sector set to grow by 20% by 2030. The majority of utility-scale wind turbines operating in the US utilize conventional horizontal axis, three blade designs, which have been adapted for offshore power production. The objective of this project is to design a vertical axis wind turbine with a wind concentrator. Vertical Axis Turbines have a low center of mass which makes it less complex structurally and easier to maintain.

This project is sponsored by Matthis Herrera

Recumbent Trike Lift | Julian a retired army veteran relies on his recumbent trike to maintain an active lifestyle, but his knee and back issues pose a challenge when it comes to loading and unloading the trike from his pickup truck.​ The goal of the project was to design a Lifting/Carrying system that allows Julian to load and unload his trike without straining his back or knees. The final design is a hitch mounted trike rack that can be lifted/lowered by an electric jack.

This project is sponsored by QL+

Eco Wash Pro MAx | A External Bottle Washer for use in industrial bottling and filling plants. the machine is capable of washing all standard 3- or 5- gallon bottles.

This project is sponsored by Steelhaed.inc

Bulk Tank Level Monitoring System | Our project is a design for a model that functionally represents bulk and day tanks at HEB’s dairy facility in San Antonio. The model will facilitate the demonstration of a control system that will monitor the fluid level in the tanks. When the fluid level in the day tanks gets low, fluid is transferred from the bulk tanks to the day tanks. The temperature of a bulk tank will be monitored for low temperature and a heater will be activated to maintain a minimum temperature. The model’s design also has provisions that allow it to be reset for subsequent demonstrations.

This project is sponsored by HEB