DEPLOYABLE INFRASTRUCTURE
POWER ON SCHEDULE
Standardized modular power blocks and thermal storage systems engineered for AI infrastructure, critical industrial operations, and national resilience requirements.
5 & 14 MW
Simple Cycle Systems
7.5 & 21 MW
Combined Cycle Blocks
N+1
Resilient Architecture
ISO CON
Form factor
The Challenge
Demand Is Outpacing Supply
- Global electricity demand is growing rapidly, driven by AI infrastructure, industrial expansion, and critical operations that require reliable, dedicated power. The need for new generation capacity is accelerating far beyond what conventional procurement timelines can deliver.
- Closing that gap requires a significant increase in the supply of deployable power generation: modular, self-contained units that can be manufactured, delivered, and commissioned on compressed timelines.
- TPS is developing advanced power generation genset packages that leverage state-of-the-art manufacturing technologies to deliver high-efficiency, low-emissions power solutions. These systems are specifically engineered for scalability, enabling cost-effective large-scale production while maintaining superior performance and reliability.
Growing Gap
Between power demand and available supply
Industry-wide lead time constraint
products: Simple Cycle
MODULAR POWER BLOCKS
Each TPS Power Block is a self-contained power generation unit housed in a standard shipping container. Units are independently operational and stack linearly. Deploy one block today and add more as demand grows.
Designed to reduce site-specific civil work and compress procurement timelines versus conventional new-build power. The units are easily transportable in either skid mounted or trailer mounted configurations.
Simple Cycle GenSet Package
Engine Overhaul, Upgrade & Testing
TPS Turbine Parts
MULTI-FUEL Capability
Vaporous Fuels:
Natural gas | Propane | Anhydrous ammonia | Hydrogen blends (up to 30%)
Liquid Fuels:
Diesel (No.1 & No. 2) | Kerosene | Jet fuels (JP-4 & Jet A) | P50 heating fuels
The simple-cycle power packages are based on two gas turbine engine platforms rated at 5 MW and 14 MW. Both engines have a proven track record of reliability in demanding applications. TPS enhances these platforms through the integration of proprietary components manufactured using advanced processes, enabling reduced emissions, improved thermal efficiency, and extended operational life.
Each genset package is equipped with a 24/7 cloud-based SCADA system, providing real-time remote monitoring and control of critical operating parameters across all deployed units. This system also integrates with the associated microgrid, ensuring optimized power delivery and system coordination.
Robust cybersecurity measures are embedded throughout the control architecture to ensure safe and secure operation. These capabilities support continuous oversight by TPS, enabling predictive maintenance strategies and proactive service scheduling to maximize uptime and reliability.
The genset packages are engineered for maintainability, with a modular design that allows rapid swap-out of major components. For example, the engine systems are configured for quick removal and replacement with pre-qualified spare units, minimizing downtime and ensuring continuous power availability.
products: Combined Cycle
Combined Cycle Power Blocks
TPS combined-cycle power blocks integrate a simple-cycle gas turbine genset with a closed-loop bottoming cycle that captures exhaust heat and converts it into additional electrical power. Unlike conventional steam-based systems, TPS utilizes a high-density working fluid, significantly denser than steam, enabling a much more compact, mobile, and rapidly deployable solution. These modular systems are delivered in skid-mounted or trailer-mounted configurations, supporting flexible deployment across a wide range of applications.
The bottoming cycle increases total power output by approximately 50% relative to the corresponding simple-cycle configuration. While conventional simple-cycle systems typically achieve real-world thermal efficiencies of ~33%, the addition of the TPS bottoming cycle raises overall system efficiency to approximately 50%. This improvement translates directly into a substantial reduction in fuel consumption—on the order of ~50% per MW generated—resulting in lower operating costs and reduced emissions intensity.
The bottoming cycle system comprises a high-speed turbine coupled to a direct-drive generator, along with compressors, high-performance heat exchangers, and integrated control systems. Key turbomachinery and thermal components are manufactured using TPS’s proprietary advanced manufacturing processes, enabling enhanced performance, durability, and system integration.
Bottoming Cycle – Skid mounted
TPS proprietary turbo-machinery
products: Energy Storage
Fluidized Matrix Thermal Battery
The Fluidized Matrix Thermal Battery (FMTB) converts low-cost, abundant materials—primarily sand and air—into a robust, long-duration energy storage solution using proven fluidized bed technology. The system stores thermal energy in sand at temperatures of up to 800°C and converts this stored heat into electricity by circulating air in a closed loop. The heated air is passed through an external heat exchanger integrated with a bottoming cycle skid—identical to those used in TPS combined-cycle power blocks—enabling efficient power generation.
The system can be charged either electrically, using resistive heaters to raise the temperature of the circulating air and sand, or thermally, by recovering waste heat from gas turbine exhaust via a heat exchanger. This dual charging capability allows seamless integration with both renewable and conventional generation sources.
FMTB systems are inherently scalable to GWh-class storage, enabling multi-day energy supply. Power output is modular and configurable through the deployment of multiple bottoming cycle skids per storage silo, with each skid providing approximately 7 MW of generation capacity. This architecture allows independent optimization of energy storage capacity and power output, making the system highly adaptable to a wide range of grid and microgrid applications.
Key Advantages of the FMTB Technology
-
Ultra-Low Storage Cost
Energy storage cost is less than one-tenth that of lithium-ion batteries, enabling economically viable large-scale and long-duration storage
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Unlimited Cycling Capability
No degradation from charge/discharge cycles, allowing effectively unlimited operational life without capacity fade.
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Inherently Safe Design
Eliminates thermal runaway risk. Utilizes non-toxic materials with no heavy metals, and all primary materials are recyclable.
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Multi-Day Energy Storage
Enables cost-effective storage over many days; capability that is not economically viable with lithium-ion systems.
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Secure and Resilient Supply Chain
Built from abundant, globally available materials, eliminating dependence on geopolitically sensitive resources.
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High Reliability and Grid Resilience
Designed with multiple layers of redundancy and capable of operating in all weather conditions. Large storage capacity enhances overall grid stability and reliability.
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Modular and Flexible Deployment
Configurable to meet specific project requirements, with the ability to deploy in a wide range of locations and applications.
The FMTB complements lithium-ion battery systems by providing cost-effective, long-duration storage while maintaining the ability to respond dynamically to load demands. Unlike electrochemical batteries, the system is not subject to cycle degradation and is capable of effectively unlimited charge and discharge cycles.
By utilizing low-cost, widely available materials and avoiding expensive or supply-constrained inputs, the FMTB offers a significantly lower capital cost profile. The system achieves a round-trip efficiency of approximately 50%, which is competitive with other emerging large-scale, non-chemical energy storage technologies, while offering superior durability, safety, and scalability.
Services
TPS provides a comprehensive suite of lifecycle services to ensure optimal performance, reliability, and long-term value of all deployed systems:
3. Asset Health & Condition Monitoring
TPS implements an integrated asset management strategy combining baseline performance benchmarking with advanced predictive analytics. All systems are equipped with embedded sensors and diagnostics, enabling continuous remote monitoring via cloud-based SCADA platforms. Operational data is continuously logged and analyzed to identify trends, optimize performance, and proactively schedule preventative maintenance, maximizing uptime and reliability
2. Warranty & Field Service Support
TPS offers comprehensive warranty coverage for all delivered equipment, backed by responsive field service capabilities. System architecture is specifically designed for rapid swap-out of major components, such as engines and generators, using pre-qualified spare units. This modular approach minimizes downtime and ensures continuous power availability.
1. Maintenance, Repair & Overhaul (MRO)
1.Full-service MRO support is provided for all system components, including gas turbine engines and associated parts, bottoming cycle turbomachinery, heat exchangers, generators, and control systems. TPS leverages its advanced manufacturing capabilities to repair, refurbish, and upgrade critical components, ensuring extended equipment life and sustained performance.
Markets
Three Demand Pools. One Common Need.
01
AI
Infrastructure
02
Industrial
Resilience
03
National
Resilience
Schedule risk is the constraint.
AI data centers and inference sites need large, reliable power blocks on timelines that outpace both grid interconnection and OEM power genset delivery. When time-to-power determines which projects get built, schedule certainty becomes the deciding factor.
Continuity risk is the constraint.
Grid and supply-chain volatility threaten operational continuity and capacity expansion. Providing a new supply of Behind-the-meter power protects operations, supports phased growth, and reduces dependence on uncertain grid capacity.
Supply chain and domestic capability risk is the constraint.
Defence Industrial Strategy links procurement to sovereign industrial capability, secure supply chains, and domestic strategic partners. Deployable power is relevant wherever energy availability is itself a strategic requirement.
Benefits of TPS Technology
TPS technology provides important benefits that serve to both help meet the rapidly growing power demand that is accelerating and also help to stabilize our existing power grids that are under increasing strain.
01
Speed to Power
TPS has developed in-house capability and new supply chains for gas turbine engines and generators that enable large scale production to help meet the power demand with much reduced delivery timelines. The containerized form factor that can be configured as skid mounted or trailer mounted reduces the site specific civil work required allowing for fast installation and commissioning.
The simple cycle power blocks will be available first. These are designed to easily integrate with the small modular Bottoming Cycle power blocks that can be added at a later time to increase the power output.
03
Grid Stabilization
The large-capacity Fluidized Matrix Thermal Battery enables deployment of distributed energy storage nodes that enhance grid stability and resilience, particularly during extended peak demand periods that place significant stress on existing infrastructure.
For large industrial power users, the system can be integrated into a microgrid alongside TPS power blocks to support behind-the-meter operation, improving energy security and cost efficiency. At the same time, it can remain grid-connected, allowing energy to be stored during off-peak periods and dispatched back to the grid during peak demand.
This dual-function capability supports load balancing, reduces peak pricing exposure, and contributes to overall grid reliability while enabling more efficient utilization of generation assets.
02
High Efficiency, Reduced Fuel Consumption
The modular Bottoming Cycle skids that can be paired with each Simple Cycle Power Block to form a Combined Cycle Power Block improves the real world efficiency from ~33% to ~50% which corresponds to a reduction of fuel consumption of about 50%. Due to the small, modular and containerized nature of the Bottoming Cycle skids, these are easily transported and installed as an upgrade to existing simple cycle power installations and they are ideally suited to be added to remote off-grid locations to reduce the logistics burden & cost of maintaining the fuel supply by ~50%.
04
Grid Independence
Each TPS unit can operate independently or as part of a multi-block system, designed for behind-the-meter or off-grid operation where site conditions allow. Adding a new supply of behind the meter power blocks off-loads the grid and reduces the strain on the grid in peak demand periods.