The CO2-free factory of the future Efficient. Sustainable. Future-proof - your vision, our path!

The factory of tomorrow combines state-of-the-art machinery with maximum resource efficiency and an energy supply based entirely on renewable sources. Intelligent, optimized logistics paths, comprehensive automation and digitalization not only enable sustainable, but also highly productive production.

Precise energy management and heat recovery systems reduce energy consumption to a minimum, setting new standards. 
Artificial intelligence controls the direct purchase of energy on the electricity exchange, meaning that efficiency and cost reduction go hand in hand.

But this is just the beginning. The CO2-free factory is a complex and multifaceted concept that combines state-of-the-art technologies, sustainable principles and innovative strategies - and ensures your long-term competitiveness.

Compensation
Renewable energies
Reduction of internal consumption

Many companies have already set out to shape this future. However, they are often faced with the challenge of pooling resources, structuring processes and making targeted progress.

Talk to us! Our specialists will work with you to develop a forward-looking strategy for your green factory. From analysis and planning to implementation, we will accompany you on your way to sustainable, efficient and emission-free production.

Our roadmap to the Green Factory offers you

  • Analysis: Precise recording of your current processes and CO2 emissions.
  • Strategy: Development of customized solutions for energy efficiency and sustainability.
  • Implementation: Support with the implementation of modern technologies and systems.
  • Optimization: Long-term support and adaptation to new challenges.

Your advantages

  • Reduce costs: Through energy efficiency and direct electricity procurement.
  • Increase sustainability: Integrating renewable energies and the circular economy.
  • Ensure competitiveness: Acting innovatively and environmentally friendly on the market.

1. Analysis phase: status quo and target definition

  • Inventory: recording current energy consumption (Scope 1, 2, 3), CO2 emissions, production processes and logistics processes.
  • Gap analysis: Identification of inefficiencies, bottlenecks and areas with high resource consumption.
  • Target definition: Definition of clear and measurable targets such as CO2 neutrality, increased energy efficiency or waste reduction.

2. Strategy development

  • Prioritization of the measures: Categorization according to costs, savings potential and feasibility.
  • Technology scouting: Investigation of modern technologies such as AI-supported energy management systems, renewable energy sources or automation solutions.
  • Profitability analysis: evaluation of the cost-benefit ratio for each measure.

3. Planning the implementation

  • Create a schedule: Define milestones, e.g. installation of PV systems or introduction of an AI-based energy optimization system.
  • Investment planning: Consider budget and funding opportunities (e.g. government subsidies for green technologies).
  • Team set-up: Clarify internal responsibilities and involve external experts if necessary.

4. Implementation of the measures

Energy

  • Introduction of renewable energies: solar, wind or geothermal systems
  • Integration of energy storage systems such as batteries or hydrogen
  • Development of an intelligent energy management system

Processes

  • Implementation of heat recovery systems
  • Digitalization and automation of production processes
  • Optimization of material flows and introduction of a circular economy concept

Logistics

  • Optimization of logistics routes through AI analysis
  • Electrification or conversion of the vehicle fleet to hydrogen technology

5. Monitoring and optimization

  • Measure and evaluate: Regular review of progress using KPIs (Key Performance Indicators) such as CO2 emissions, energy consumption or production costs.
  • Flexible adjustment: Identify and rectify deviations from the plan
  • Continuous improvement: incorporate feedback loops and respond to new technologies

6. Communication and training

  • Creating transparency: Disclosure of the carbon footprint and progress in the sustainability strategy
  • Employee training: Further training on sustainable practices and technologies
  • Involve stakeholders: Informing customers, partners and the public about progress

7. Milestones on the way to the Green Factory

  • Short term (1-2 years):
    • Introduction of energy efficiency measures
    • Conversion to green electricity
    • Implementation of initial automation projects
  • Medium-term (3-5 years):
    • Development of own renewable energy sources
    • Integration of a comprehensive energy management system
    • Creation of a circular economy within production
  • Long-term (5-10 years):
    • Achieve CO2-free production
    • Complete digitalization and automation of processes
    • Integration into a regional or global “green factory” value chain

Results of the roadmap

  • A clear, prioritized plan that enables the transformation of the factory in a realistic timeframe
  • Precise steps for implementation with associated responsibilities and KPIs
  • A sustainable, future-proof approach that combines ecological and economic success

Start your journey
to the Green Factory of the future!

Arrange an appointment now

Kathrin Selzer

Dipl. Ing. (FH) Supply engineering, 
Managing director of the company

Florian Stelling

M.Eng. Energy systems engineering, 
Project manager energy consulting and promotion