We remove the constraints that limit how hardware can be designed and built
Through material-led computational engineering and design for additive manufacturing, we turn system complexity into monolithic, high-performance hardware with predictable adoption and delivery.
Discover DfAM and material-led Computational engineering at Novare Additive
Discover DfAM and material-led Computational engineering at Novare Additive.
Energy · Ocean · Industrial hardware
Our Mission, Purpose and Ambition
Mission
We help energy and industrial companies turn complex assemblies into monolithic, high‑performance components through a one‑stop delivery model.
Purpose
To eliminate the system complexity and capital friction that make advanced energy and industrial hardware expensive to industrialize and scale.
Ambition
To make additive‑first engineering a trusted, mainstream standard for critical energy and ocean‑industrial hardware.
What we mean by system complexity and capital friction
In critical energy and industrial hardware, cost and risk are rarely driven by individual components. They are driven by system complexity: many parts and interfaces, compatibility constraints, fragmented supply chains, manual integration, qualification effort, and unpredictable delivery.
Crucially, this complexity also obscures structural and functional intent. When Design for X (DfX) is not closed early through analysis and simulation — spanning structural behaviour, manufacturability, assembly, and lifecycle — right‑first‑time delivery becomes rare and iteration unavoidable.
Design for Additive Manufacturing (DfAM) enables DfX at system level by consolidating functions into fewer, high‑value parts. This makes load paths, material utilisation, logistics, assembly, automation, and end‑of‑life handling explicit by design — enabling predictable industrialisation, full traceability, and simplified reuse and recycling.
What We Do
Novare Additive helps energy and industrial companies design and realize additive‑first hardware and products where it creates real system‑level value.
We focus on hardware where performance, reliability, lead time, or scalability are constrained by system complexity — not by materials or physics.
Our Approach
Material‑led design
Material compatibility and precise material placement form the foundation of un‑design.
We design from physics and material behaviour, using analysis and simulation rather than legacy CAD assumptions.
Monolithic integration
We replace fragmented assemblies with fewer, more reliable components — reducing interfaces, integration risk, and system complexity.
Predictable delivery
We reduce adoption risk through a one‑stop model from design to delivery, built on trusted manufacturing and qualification partners.
Why This Matters
In critical energy and industrial hardware, scaling is rarely limited by innovation. It is limited by integration risk, qualification effort, and capital intensity.
Additive manufacturing creates system‑level value when applied through Design for Additive Manufacturing (DfAM) to redesign system architecture — not when legacy assemblies are simply reproduced in print.
Who We Work With
We work with energy, ocean, and industrial companies developing hardware where reliability, performance, and scalability are critical — and where system complexity, qualification effort, and long lead times have become barriers to progress.
Building step by step
Novare Additive is an early‑stage engineering initiative exploring additive‑first design for scalable energy and industrial hardware, built step by step in close collaboration with industry and academia.
We believe trust, reliability, and scalability are earned — not claimed