El Programa XM30 del US Army tiene por objetivo el desarrollo de un Vehículo de Combate de Infantería (IFV) que reemplace al reconocido IFV Bradley, en servicio desde la década de los 80 ‘s. Se espera que el sistema otorgue renovadas capacidades a las unidades blindadas. Especialmente en lo relacionado con el poder de fuego del nuevo cañón calibre 50 x 228 mm montado en una torre autónoma del tipo WRS (Weapon Remote Station), sistemas de misiles antitanque guiados gemelos (ATGM’s) y un moderno Sistema de Control de Tiro asistido por Inteligencia Artificial (AI). Con una tripulación de 2 hombres, capacidad para llevar 6 soldados y una buena relación entre poder de fuego – peso – protección blindada – movilidad, deberá ser capaz de operar conjuntamente con las futuras versiones del tanque M1 Abrams o nuevas plataformas que eventualmente lo reemplacen.
The XM30 is expected to bring significant changes to the infantry fighting vehicle (IFV) category, featuring a 50×228 mm cannon in a remote-controlled turret, twin Anti-Tank Guided Missiles (ATGMs), an AI-enabled fire control system, and a hybrid drivetrain. The XM30 will have a crew of two (a driver and a commander) and will carry six infantry personnel. The vehicle’s size and capacity have been designed to maintain a balance between firepower and mobility while preventing it from becoming too large or heavy, as seen with some past IFV designs. It will be designed to work alongside future versions of the M1 Abrams and is expected to include protection against Unmanned Aerial Systems (UAS).
Digital engineering has been central to the development of the XM30. In the early phases of the program, five contractors were given approximately $60 million each to create digital designs based on draft requirements from the Army. Through this process that facilitated its design, development, and potential future upgrades, the US Army refined the vehicle’s requirements and ensured they were achievable, avoiding issues that led to the cancellation of earlier programs. For instance, by using 3D models and simulations early in the design phase, the Army ensures that all requirements and subsystems, including sensors and fire control mechanisms, are aligned before physical prototypes are constructed. This approach minimizes development costs and helps contractors and the Army quickly address any design issues that arise during the process.
The modular design of the XM30 supports future technological updates, enabling the integration of new systems with minimal changes to the vehicle’s core architecture. Equipped with a hybrid-electric drivetrain and a variety of weapon systems, including a 50mm cannon and anti-tank guided missiles, the XM30 is configured to meet current operational requirements while maintaining flexibility for future needs. The vehicle’s reduced crew size and its capacity to transport infantry are aimed at improving operational efficiency without increasing size or complexity.
The XM30 program is a continuation of the US Army’s efforts to replace the M2 Bradley, which has been in service since the 1980s. Despite several earlier attempts, including the Ground Combat Vehicle and Future Combat System programs, previous initiatives were not successful, often due to issues with aligning requirements, funding, technology, and schedule. Colonel Jeffery Jurand, the project manager for the XM30, has emphasized that the current program is aligned in these areas, supported by the use of digital engineering. This approach allows for the design and testing of the vehicle through digital models, avoiding some of the challenges faced by earlier programs.
Both General Dynamics and Rheinmetall were selected to move forward in the competition, with the Army currently in phase three of a five-phase schedule. These contractors will deliver prototypes by late 2026, with the Army conducting critical design reviews by the first half of fiscal year 2025. The final selection of a single vendor for production will take place around the first quarter of fiscal year 2028, after testing and evaluation of the prototypes.
The program is also supported by the “digital trinity” approach, which includes models-based systems engineering, digital engineering, and development, security, and operations (DevSecOps). This digital approach has allowed for improved traceability and communication between contractors and the Army, with errors being identified and addressed earlier in the design process. The open architecture of the XM30 design has been highlighted as a way to accommodate future upgrades and reduce costs.
The XM30 is one of six pathfinder programs identified by the Army to demonstrate the benefits of digital engineering. The Army’s use of digital engineering for this project is intended to improve design efficiency, reduce costs, and ensure the vehicle’s modularity and adaptability for future needs. The program has drawn confidence from senior Army leaders, who have expressed support for its goals and its potential to provide long-term benefits, including cost savings through its open architecture.
As the program moves forward, the remaining phases will focus on prototype development, testing, and evaluation. The Army is scheduled to begin testing the prototypes in 2026, with a final decision on production expected in 2028.
Fuente: https://www.armyrecognition.com