Clean Fuel, Clean Future
Advanced Desulfurization Technology for Liquid Fuels

Our Story

Innovating since 2010, we've been transforming ideas into digital reality with passion and precision.

Who We Are

Our Mission

We empower businesses through innovative digital solutions that drive growth and create meaningful connections with their audiences. Our team of experts is dedicated to delivering exceptional results through cutting-edge technology and creative thinking.

With a customer-centric approach, we tailor our services to meet the unique needs of each client, ensuring measurable success and long-term partnerships.

Our Vision

To be the global leader in digital transformation, recognized for our ability to turn complex challenges into elegant solutions that propel businesses forward in an ever-evolving digital landscape.

We envision a future where technology enhances every aspect of business operations, and we're committed to being at the forefront of this transformation.

By The Numbers

250+

Satisfied Clients

500+

Completed Projects

50+

Dedicated Professionals

15+

Countries Served

S W O T

Analysis of Oxidative Desulfurization Technology

STRENGTHS

  • Operates at mild temperatures and pressures versus hydrodesulfurization
  • Smaller, less costly equipment than hydrotreating
  • Preserves more fuel energy density and octane levels
  • Has simple operation and short reaction times

WEAKNESSES

  • Not effective at removing certain recalcitrant sulfur compounds
  • Consumes and regenerates oxidizing agents, adding operating complexity
  • Can have issues with selectivity and competing side reactions
  • Sulfur compounds are converted to waste products, not valuable byproducts

OPPORTUNITIES

  • Usually used as a polishing step after hydrotreating
  • Tighter sulfur specifications requiring deep desulfurization
  • Integration with renewable hydrogen peroxide production methods
  • Modular construction allowing for incremental capacity increases
  • Further process optimization through catalyst development

THREATS

  • Commoditization putting pressure on fuel prices and margins
  • Changes in regulatory support for renewable oxidant production
  • Competition from advanced hydrotreating technologies
  • Public opposition to expanded liquid fuel refining facilities
  • Declining long-term demand outlook for liquid transportation fuels



Competitive Analysis: ODS vs HDS Technologies


Comparative Parameters Advantage
Hydrogen addition/catalyst Yes No ODS
Equipment cost $12,000/barrel/day 25-30% or less of HDS ODS
Operating costs $4-5/bbl. $1.5-2/bbl. ODS
Pressure 2000 PSI 50 PSI or less ODS
Temperature 300-400 ℃ 80℃ or less ODS
Operation Complex, several operators Simple, 1 to 2 operators ODS
Effect on octane/cetane number Reduced No effect ODS
Environmental regulations Carbon footprint Without carbon footprint ODS
Movable No Yes ODS
Removal of complex sulfur compounds Less effective for cyclic compounds Effective with all sulfur compounds ODS

Key Takeaways

  • ODS demonstrates superior cost efficiency across all metrics
  • Significantly simpler operational requirements with ODS
  • ODS offers environmental advantages with lower carbon impact
  • Better technical performance in sulfur removal



Risk Assessment & Mitigation Strategies

Comprehensive safety analysis for oxidative desulfurization operations

Acute toxicity hazards to workers and surroundings from uncontrolled release of NO2 gas or acidic liquids.

Contingency Plan:

  • Install monitoring and containment systems
  • Maintain neutralization capacity
  • Provide comprehensive PPE and training
  • Implement emergency response protocols

Highly corrosive conditions degrading critical equipment components like reactors, pipes, and tanks.

Contingency Plan:

  • Use corrosion-resistant alloys for all critical components
  • Maintain spare parts inventory
  • Implement stringent inspection routine
  • Apply protective coatings and cathodic protection

Exothermic reactions and variable process parameters increasing instability risk.

Contingency Plan:

  • Rigorously model process conditions
  • Engineer relief systems
  • Automate controls
  • Shutdown procedures

Water and electricity outages disrupting operations and safety systems.

Contingency Plan:

  • Install backup generators and UPS systems
  • Maintain emergency water supply
  • Implement redundant critical systems
  • Develop emergency shutdown procedures

Additional Safety Measures

Earthquake-resistant structural design

Fire suppression systems installation

Redundant equipment and spare parts

Continuous process monitoring systems




Laboratory Stage

From Concept to Validation
Experimental Validation

We had an idea that has been tested in the laboratory. At this stage, about 200 laboratory tests were performed on the condensate. In each experiment, 2 liters of condensate were tested and the sweetened product was about 1.9 liters with the lowest amount of sulfur content.

0
Laboratory Tests
0
% Efficiency

Our goal is to validate these steps with any kind of condensate produced in Canada or any high-sulfur fuels in Canada. In the appendix section, more the details of laboratory stage are presented.

Laboratory Experiment
Schematic representation of the reactor and shear mixer applied in the experiments: (a) front view, and (b) bottom view



Our Core Values

Innovation

We constantly push boundaries to deliver cutting-edge solutions that set our clients apart in their industries.

Integrity

We build trust through transparency, honesty, and ethical business practices in all our relationships.

Collaboration

We believe the best results come from teamwork, both within our organization and with our clients.

Excellence

We're committed to delivering exceptional quality in everything we do, exceeding expectations at every turn.

Ready to Transform Your Business?

Let's create something amazing together. Our team is ready to bring your vision to life.

Get In Touch