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Dispatchable Renewable Infrastructure

Renewable
Electricity.
On Demand.

Renewable Electricity. On Demand. At Industrial Scale.

Long-duration dispatchable renewable power designed for remote industrial operations where reliability is mission critical.

Focus Market
Remote Mining AU
Storage Target
100+ Hour Duration
Site Status
Pilot Secured
Research
UTS Collaboration
Funding
Grant Apps Active

The Problem

Renewables Changed
Generation.
Not Reliability.

The world has made extraordinary progress in renewable energy generation. The problem it has not solved is dispatchability — the ability to deliver power precisely when it is needed, not when the sun shines or wind blows.

Remote industrial operations require guaranteed uptime. Today, that guarantee still comes from diesel.

01
Remote mines remain diesel-dependent
Australia's remote mining sector consumes millions of litres of diesel annually, creating significant operational cost and supply chain risk.
02
Batteries cannot solve long-duration needs
Lithium-ion storage degrades economically beyond 4–8 hours. Remote operations require days, not hours, of reliable backup capacity.
03
AI is accelerating electricity demand globally
Data centres and industrial computing are creating new categories of high-reliability electricity demand that existing grids were not designed to serve.
04
The dispatchability gap is widening
As renewable penetration increases, the economic cost of intermittency rises. The gap between generation and reliable delivery is growing — not shrinking.
Operational Reality — Remote Mining Status Quo
Primary GenerationDiesel Generators
Fuel Logistics RiskCritical Exposure
Long-Duration StorageUnavailable
Carbon LiabilityIncreasing
Operational CertaintyFuel-Dependent
RESET Infrastructure Target State
Primary GenerationRenewable + Stored
Fuel Logistics RiskMaterially Reduced
Long-Duration Storage100+ Hours
Carbon LiabilityReduced Exposure
Operational CertaintyDispatchable

The RESET Solution

A New Category Of
Dispatchable Renewable
Infrastructure

RESET integrates six engineered layers into a single system — combining mechanical, thermal, and software technologies to deliver reliable power regardless of weather or grid conditions.

Solar Input
Renewable capture at scale. Optimised for high-irradiance remote environments.
A-CAES Storage
Adiabatic compressed air. Long-duration mechanical energy storage.
Al-Salt Battery
Aluminium salt thermal battery layer for extended duration reserve.
50M
Gravity Tower
50m gravity induction tower. Gravitational potential energy dispatch.
Power Electronics
Inverters, conversion systems, and grid-synchronisation hardware.
AI Control Layer
Predictive dispatch, load forecasting, and autonomous optimisation.
The RESET Thesis
"The world doesn't have a renewable generation problem.
It has a dispatchability problem."

System Operation

How RESET Works

Five integrated stages transform intermittent renewable input into continuous, on-demand, grid-compatible power output.

01
Capture Renewable Energy
Solar generation captures available renewable energy during peak production hours, maximising capture across variable irradiance conditions typical of remote Australian environments.
Input SourceSolar PV
Target RegionHigh-irradiance remote
02
Store Energy Mechanically
Excess generation converts to mechanical energy via the A-CAES system and gravity tower. Mechanical storage has fundamentally different degradation characteristics to electrochemical batteries, enabling long-duration economics.
Storage MethodA-CAES + Gravity
DegradationLower cycle target
03
Maintain Long-Duration Reserve
The aluminium salt battery layer provides a thermal buffer, extending effective storage duration well beyond what mechanical storage alone delivers. The combined system targets 100+ hour capacity.
Duration Target100+ Hours
Reserve LayerAl-Salt thermal
04
Dispatch Power On Demand
The AI control layer continuously models load requirements, storage state, and generation forecasts. Dispatch decisions are made autonomously in real time, delivering stored energy precisely when needed.
ControlAI-autonomous
ResponseReal-time dispatch
05
Deliver Grid-Compatible Electricity
Power electronics condition and convert stored energy to stable, grid-compatible electricity meeting industrial power quality standards, enabling direct integration with existing mine electrical infrastructure.
OutputGrid-compatible AC
IntegrationDrop-in replacement

Commercial Model

Diesel Spend Becomes
RESET Revenue

RESET converts a mining operation's largest variable cost — fuel — into a long-term contracted infrastructure service. The business model is designed for institutional-grade cash flow predictability.

Energy-as-a-Service (EaaS)
Long-term power purchase agreements with mining operators. RESET owns, operates, and maintains the infrastructure. The mine pays per MWh delivered.
Infrastructure Ownership
RESET retains ownership of deployed infrastructure, generating long-duration asset value and creating an expandable infrastructure portfolio.
Software & AI Layer
Proprietary control software generates recurring revenue through licencing and managed service agreements across the RESET deployment network.
O&M Services
Operations and maintenance contracts provide steady-state revenue streams with low marginal cost as the deployment network scales.
Carbon Credits
Verified emissions reductions from diesel displacement generate carbon credit revenue, strengthening the commercial case alongside energy savings.
IP Licensing
Proprietary technology and validated designs create licensing revenue opportunities across international markets as the RESET IP portfolio matures.
Current Reality
A$42.6M
Annual diesel spend
10 MW remote mine
RESET
Converts To
RESET Revenue
EaaS PPA
Long-term contracted revenue
Infrastructure-backed

Case Study

10 MW Remote
Mining Deployment

Model Site — Pilbara, Western Australia

The Sanjiv Ridge project models RESET's commercial proposition against a real-world remote mining energy profile, demonstrating the economic compulsion driving operator interest.

10 MW
Modelled Load
78,840
MWh Annual Demand
17.7M L
Annual Diesel
Pilbara
WA Location
Diesel Cost — Low Scenario
A$31.9M
Per annum at current pricing. Exposed to fuel supply and logistics risk.
Diesel Cost — High Scenario
A$42.6M
Per annum under elevated fuel cost conditions. Carbon liability not included.
RESET EaaS Pricing
Competitive
RESET pricing below diesel parity, locking in operator savings and RESET revenue simultaneously.
Annual Energy Cost Comparison — Sanjiv Ridge Model (A$ Million)
A$31.9M
Diesel
Low
A$42.6M
Diesel
High
RESET EaaS
RESET
EaaS
Savings
Operator
Saving

Market Opportunity

A Global Reliability
Opportunity

RESET's dispatchability infrastructure addresses a reliability gap across multiple high-value sectors globally. The addressable market expands significantly as RESET deploys beyond its initial mining focus.

Primary Market — Stage 1
Remote Mining Operations
Australia
Australia hosts over 400 remote mines, many of which remain diesel-dependent. The Pilbara, Goldfields, and Northern Territory represent the highest-intensity diesel consumption in the sector. RESET's first commercial deployments are targeted here.
Stage 2 Expansion
Data Centres
AI-driven electricity demand growth is creating critical need for dispatchable backup power at data centre scale. RESET's architecture is directly applicable.
Geographic Expansion
Pacific Islands
Island communities face extreme diesel dependency and energy insecurity. RESET's modular infrastructure offers a deployable solution at community and industrial scale.
Strategic
Defence Infrastructure
Defence operations in remote theatres require resilient, fuel-independent power. Dispatchable clean energy is strategically aligned with sovereign capability objectives.
Social Infrastructure
Remote Communities
Thousands of Australians in remote communities remain dependent on expensive diesel generation. RESET's technology is scalable to community load profiles.
Critical Systems
Critical Infrastructure
Water treatment, communications, and logistics infrastructure in remote areas require reliable, maintainable power independent of fragile supply chains.

Validation Pathway

De-Risking Through
Independent Validation

RESET's commercialisation pathway is structured to progressively validate each technical and commercial assumption. Each stage de-risks the investment thesis and prepares the path to full commercial deployment.

Concept Development
Engineering Design
Prototype Build
04
Digital Twin Validation
05
UTS Validation
06
Pilot Deployment
07
Commercial Rollout
University of Technology Sydney
Research Partner
UTS collaboration for independent technical validation. Prof. Youguang Guo and A/Prof. Yam Siwakoti leading research engagement.
DeepDish Engineering
Engineering Partner
Independent engineering design, review, and validation providing professional oversight across RESET's system architecture.
ARC Linkage Program
Grant Pathway
Australian Research Council Linkage application active. Industry-university collaborative research funding supporting prototype and validation stages.
Pilot Site
Deployment — Secured
First pilot deployment site secured. Real-world operational conditions will validate modelled performance and provide bankable commercial data.

Leadership & Validation

The Team Behind RESET

RESET is led by a team combining systems architecture expertise and operational leadership — supported by independent research and engineering validation from UTS and DeepDish Engineering.

SA
Scott Anderson
Founder & Systems Architect
Founder of RESET and originator of the integrated system architecture. Scott leads the technical vision behind RESET's approach to long-duration dispatchable renewable power for remote industrial operations.
DC
Darren Clarke
Chief Executive Officer
Chief Executive Officer of RESET, responsible for commercial strategy, operational execution, partnerships, and deployment planning as the company advances from prototype validation toward pilot and commercial rollout.
UTS Research Partners
Prof. Youguang Guo
UTS Research Partner
A/Prof. Yam Siwakoti
UTS Research Partner
UTS Research Team
University of Technology Sydney

Investment Opportunity

Building The Future Of
Dispatchable Renewable Power

RESET is at the pivotal stage between proven concept and validated prototype. Investment at this stage funds the work required to produce independently validated, bankable technical and commercial evidence — the foundation of commercial-scale deployment.

Pre-Revenue Stage
Early-stage entry with significant upside exposure prior to commercialisation
Pilot Site Secured
Real deployment site confirmed for first operational validation
University Research Active
Independent technical validation through UTS research partnership
Grant Applications Active
Non-dilutive grant funding pathways underway, including ARC Linkage
IP Development Pathway
Proprietary technology portfolio development in progress
Current Funding Objectives
Prototype DevelopmentStage 1
Independent ValidationStage 2
Digital Twin BuildStage 3
Pilot DeploymentStage 4
IP DevelopmentOngoing
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Partners & Supporters

Institutional Relationships
& Research Network

UTS
University of Technology Sydney
Research Partner
DDEng
DeepDish Engineering
Engineering Partner
ARC
Australian Research Council
Grant Program
ARENA
Australian Renewable Energy Agency
Grant Pathway

Contact

Start The
Conversation

RESET welcomes inquiries from institutional investors, strategic partners, research institutions, and government agencies. Our team will respond within two business days.

EntityRESET Energy Pty Ltd
LocationAustralia
FocusRemote Mining — Pilbara, WA
EmailScott@hcgbtechnologies.com
LinkedInRESET on LinkedIn ↗

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Renewable Electricity. On Demand. At Industrial Scale.