From December 31, 2024, you will need a BAFA-certified monitoring system for buildings with a consumption of more than 290 kW.

This means that non-residential buildings with an HVAC capacity of 290 kW are required to implement a certified energy management system (§ 71a).
The following are required: monitoring and analysis of energy consumption, automatic detection of malfunctions and inefficiencies, predictive control of HVAC.

We would like to remind you that HiPerWare is an officially recognized, BAFA-certified EMS that helps you comply with § 71a GEG and the requirements of the EnEfG and offers additional benefits: government support, energy savings of 10–30%, and proactive building operation based on AI.
If your system has a capacity of 290 kW or more, or if you are planning to modernize your HVAC system, please contact us. It is time to increase efficiency and prepare for the new regulations.

Improve energy efficiency of your business by implementing AI-driven big data solution:

• Access smart analysis of energy usage and waste
  
• Get valuable insights into usage patterns and areas for improvement
• Lower energy bills up to 66% and reduce CO2 emissions up to 100%, minimising environmental impact, and improving assets' sustainability

HiPer it! offers an innovative solution, designed to guide companies towards achieving energy efficiency and minimising reliance on fossil fuels. It measures how energy is generated, distributed, used, stored and lost in real time with dynamic Business Energy Model (BEM), created by the HiPerWare platform. Additionally, ​HiPerWare ensures efficient operations after energy retrofit implementation.

Innovative methodology – redefining energy optimisation

HiPer it! developed the Dynamic BEM audit that identifies optimisation opportunities in the following 6 key components of the facility’s energy efficiency:

1. Thermal insulation of building envelope performance (building thermal envelope). The facility should not exhibit any anomalies in energy retention (heat or cold).

2. Energy consumption on real demand (seasons, weather, workdays, shifts, occupancy, etc.). Energy should be consumed dynamically, following the principle of "necessary and sufficient“

3. Elimination of energy waste*. Ensuring that maximum energy from internal sources is utilised efficiently.
*​Energy waste is worthless, harmful or hazardous excess energy that must be discharged, incurring additional costs.  An example is heat from the operation of building or production equipment. Energy waste is usually discharged into the environment, increases greenhouse gas emissions and causes thermal pollution. 

4. Dynamic generation with maximum efficiency. Heat or cold generation in optimal operational modes and favorable weather conditions (max COP / EER, etc.).

5. Peak shaving and spot energy consumption. Utilising optimal equipment scheduling, use energy storage to smooth consumption peaks, capitalise on spot energy prices during low-cost periods.

6. Analysis of ​building systems operations​.  In-depth continuous analysis of technical operations, detection of anomalies and sub-optimality of processes occurring in the building systems to reduce energy consumption and optimise technical operations.