HPQ Silicon Inc. (“HPQ” or the “Company”) (TSX-V: HPQ,
OTCQB: HPQFF, FRA: O08), a technology company
specializing in the green engineering of silica and silicon-based
materials is pleased to inform shareholders of a patent filing
related to its Silicon-based anode material initiatives.
HPQ filed a provisional patent application in France, expanding
its pending patent for the continuous SiOx manufacturing process.
The patent outlines the critical technologies and processes
required for the continuous or semi-continuous production of
high-performance silicon-based materials.
Patent Expands HPQ Portfolio of Silicon for
Battery-Based Proprietary Technologies
As previously disclosed—HPQ’s France-based affiliate, NOVACIUM
SAS ("Novacium"), has demonstrated a unique capability to produce
silicon-based anode materials that can:
- Deliver over 4,000
milliampere-hours (mAh) in 18650 lithium-ion batteries under
maximum discharge conditions [1],
- Retain 3,608 mAh, or
93% of its capacity, after 300 cycles under a rigorous testing
protocol [2], and
- Be seamlessly
integrated into existing manufacturing processes without costly
retooling or overhauls.
As part of its strategy to manufacture and commercialize
engineered silicon-based materials that can deliver these results
at scale, HPQ filed the patent application to expand its downstream
capabilities beyond the existing patented continuous SiOx
manufacturing process. This application covers the apparatus and
methods necessary for the continuous or semi-continuous
high-throughput production of GEN3 and beyond engineered
silicon-based materials suitable for Li-ion battery anodes.
"While Silicon (Si) is abundant and cost-effective, offering
immense promise for advancing energy storage technology,
particularly in batteries, integrating silicon into battery systems
still presents technical and economic challenges,” said Bernard
Tourillon, President and CEO of HPQ Silicon Inc. “The
high-performance, engineered silicon-based materials covered by
this patent can overcome many of these hurdles, making it possible
to unlock the full potential of silicon and turn it into a viable
solution for next-generation energy storage across various
industries."
Making High-Performance Engineered Silicon-Based
Batteries Materials, A Multi-Step Process
Step 1: Converting Quartz (SiO₂) into Metallurgical
Grade Silicon (MG Si)
This step involves using a carbothermic process to transform
Quartz (SiO₂) into Metallurgical Grade Silicon (1N to 2N Si, or MG
Si), followed by refining MG Si into Upgraded Metallurgical Grade
Silicon (3N to 4N Si, or UMG Si).
Current industrial processes for silicon production are
capital-intensive, with minimum output increments of 30,000 to
50,000 tonnes per year (TPY) [3] and come with high variable costs
[4]. Producing 1 tonne of MG Si requires 6 tonnes of feedstock and
approximately 12,000 kWh of energy. Refining MG Si to UMG Si
involves extra purification steps, which further increase variable
costs and contribute to the high CO2 footprint.
HPQ’s patented PUREVAP™ Quartz Reduction Reactor (QRR) offers an
enclosed carbothermic process with a zero CO2 footprint [5]. It is
scalable by increments as low as 1,000 TPY and can convert Quartz
directly into Upgraded Metallurgical Grade Silicon in a single
step, using 25% less feedstock.
Currently, MG Si sells for between US$2 and US$3 per kg, while
UMG Si sells for between US$4 and US$6 per kg [6].
Step 2: Manufacturing SiOx, the Key
Feedstock
SiOx is manufactured via the sublimation of quartz (SiO₂) and
Upgraded Metallurgical Grade Silicon (UMG Si) in reactors. Current
industrial processes for SiOx production are batch-based, limiting
productivity, increasing costs, and leading to higher energy
consumption.
HPQ’s patented process addresses these limitations by
transitioning to continuous SiOx production. This process increases
productivity threefold, reduces energy consumption by 20%, and
lowers costs by 25-30%. Additionally, it produces higher-quality
silicon-based materials with greater homogeneity and less
contamination, making them better suited for the battery market
with a low carbon footprint [5].
Another key advantage is that this process can be seamlessly
integrated into HPQ’s QRR without requiring significant changes to
reactor design, minimizing technological development risks.
Depending on purity and quality, SiOx currently sells for
between US$10 and US$20 per kg [6].
Step 3: Encapsulating SiOx in Carbon
Current industrial processes for encapsulating SiOx in carbon
are batch-based, which limits productivity, increases costs, and
results in higher energy consumption. HPQ’s new process aims to
transition to continuous or semi-continuous, high-throughput SiOx
production with carbon encapsulation, increasing productivity,
reducing energy consumption, and lowering manufacturing costs.
Depending on purity, quality, and performance,
carbon-encapsulated SiOx currently sells for between US$25 and
US$50 per kg [6].
Step 4: Upgrading material to highly engineered
silicon-based anode materials
Upgrading the material produced in step 3 into highly engineered
silicon-based anode materials further enhances battery performance,
providing greater energy density and overall efficiency for
next-generation energy storage solutions. HPQ’s new process aims to
transition to a continuous or semi-continuous transformation of the
materials produced in step 3 into highly engineered silicon-based
anode materials. This approach will increase productivity, reduce
energy consumption, and lower manufacturing costs.
Today, highly engineered silicon-based anode materials are
priced between US$60 and US$100 per kilogram [5] depending on
quality and performance.
“This new patent application, along with the validated potential
of our material, further strengthens our unique value proposition
in the silicon-based anode materials market," added Mr. Tourillon.
"What truly sets us apart from other players in the field is that
our primary feedstock is low-cost metallurgical silicon metal,
rather than the much more expensive and volatile monosilane
gas(SiH4) [7] which also requires a costly Chemical Vapor
Deposition (CVD) process to produce battery-grade silicon
materials.”
Silicon-Based Materials Market to Grow in tandem with
Increasing Lithium Battery Demand.
Approximately 95% of the anode material in today's Li-ion
batteries is graphite [8]. HPQ’s silicon-based material, capable of
seamlessly integrating into existing manufacturing processes and
replacing more than 10% of that graphite without costly retooling
or overhauls, should positions us to capture a significant portion
of the addressable market, ranging from 10% to 15% of the total
graphite market, both now and in the future.
The global graphite market by volume, as estimated by Benchmark
Minerals Intelligence (BMI), is projected to grow from
approximately 700,000 tonnes in 2021 to 4.5 million tonnes by 2030
[9]. This growth translates into an addressable market of 450,000
to 675,000 tonnes for our material by 2030, valued between US$22.5
Billion and US$33.8 Billion [10].
“HPQ’s strategy will focus first on producing silicon-based
materials for the 3C markets (Computer, Consumer, and
Communication), as this US$ 12 Billion market now, projected to
grow to US$ 38.3 Billion in 2030 [11] is perfectly suited for the
materials we’ve already validated at this stage of our
development,” added Mr. Tourillon. “Our market focus will also
expand to energy storage and electric vehicles overtime.”
REFERENCE SOURCES
[1] |
Link to HPQ press release of July 30th 2024. |
[2] |
Link to HPQ press release of October 8, 2024. |
[3] |
Management estimates based on the size of the last new silicon
metal plants built outside of China, Mississippi Silicon and the
latest silicon metal production plant in Iceland. |
[4] |
Management estimates based on a review of Ferroglobe Investors Deck
since 2014. |
[5] |
Link to HPQ press release of June 27, 2023. |
[6] |
Management estimates based on confidential price quotes received
for materials by HPQ affiliated company. |
[7] |
Silane gas presents several significant hazards that make it
particularly dangerous. It is highly flammable and pyrophoric,
meaning it can ignite spontaneously upon exposure to air. In
addition, when silane is inhaled, it can transform into silicic
acid within the body, leading to tissue irritation and other health
problems. And the production of silane gas involves the use of
extremely hazardous materials, including chemicals that are toxic,
corrosive, and environmentally damaging. (Source: Solar Industry
Magazine) |
[8] |
Link to source for Graphite in batteries |
[9] |
Link to source for Benchmark Minerals Intelligence (“BMI”)
estimates. |
[10] |
The US $ 22.5 Billions is taken by multiplying 450,000 t by US$ 50
per Kg, while the US$ 33.8 Billions is taken by multiplying 600,000
t by US$ 50 per Kg. |
[11] |
Link to source for 3C market date. |
About HPQ
HPQ Silicon Inc. (TSX-V: HPQ) is a
Quebec-based TSX Venture Exchange Tier 1 Industrial Issuer.
HPQ is developing, with the support of
world-class technology partners PyroGenesis Canada Inc. and
NOVACIUM SAS, new green processes crucial to make the critical
materials needed to reach net zero emissions.
HPQ activities are centred around the following
four (4) pillars:
|
1) |
Becoming a green low-cost (Capex and Opex) manufacturer of Fumed
Silica using the FUMED SILICA REACTOR, a
proprietary technology owned by HPQ Silica Polvere Inc being
developed for HSPI by PyroGenesis. |
|
2) |
Becoming a producer of silicon-based anode materials for battery
applications with the assistance of NOVACIUM SAS. |
|
3) |
HPQ SILICON affiliate NOVACIUM SAS is developing a low carbon,
chemical base on demand and high-pressure autonomous hydrogen
production system. |
|
4) |
Becoming a zero CO2 low-cost (Capex and Opex) producer of High
Purity Silicon (2N+ to 4N) using our
PUREVAPTM “Quartz
Reduction Reactors” (QRR), a proprietary technology owned
by HPQ being developed for HPQ by PyroGenesis. |
For more information, please visit HPQ Silicon
web site.
Disclaimers:
This press release contains certain
forward-looking statements, including, without limitation,
statements containing the words "may", "plan", "will", "estimate",
"continue", "anticipate", "intend", "expect", "in the process" and
other similar expressions which constitute "forward-looking
information" within the meaning of applicable securities laws.
Forward-looking statements reflect the Company's current
expectation and assumptions and are subject to a number of risks
and uncertainties that could cause actual results to differ
materially from those anticipated. These forward-looking statements
involve risks and uncertainties including, but not limited to, our
expectations regarding the acceptance of our products by the
market, our strategy to develop new products and enhance the
capabilities of existing products, our strategy with respect to
research and development, the impact of competitive products and
pricing, new product development, and uncertainties related to the
regulatory approval process. Such statements reflect the current
views of the Company with respect to future events and are subject
to certain risks and uncertainties and other risks detailed from
time-to-time in the Company's ongoing filings with the security’s
regulatory authorities, which filings can be found at
www.sedar.com. Actual results, events, and performance may differ
materially. Readers are cautioned not to place undue reliance on
these forward-looking statements. The Company undertakes no
obligation to publicly update or revise any forward-looking
statements either as a result of new information, future events or
otherwise, except as required by applicable securities laws.
Neither the TSX Venture Exchange nor its
Regulation Services Provider (as that term is defined in the
policies of the TSX Venture Exchange) accepts responsibility for
the adequacy or accuracy of this release.
This News Release is available on the
company's CEO Verified Discussion Forum, a moderated social
media platform that enables civilized discussion and Q&A
between Management and Shareholders.
Source: HPQ Silicon Inc.For further
information contact: Bernard J. Tourillon, Chairman,
President, and CEO Tel +1 (514) 846-3271Patrick Levasseur, Director
Tel: +1 (514) 262-9239Email: Info@hpqsilicon.com
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