Sustainability Archivi - Techniconsult

Techniconsult Group Achieves B Corp Certification

Techniconsult Group — Tue, 12 May 2026 08:06:58 +0000

The original Italian version is the sole official and authorized text. This English translation is provided for informational purposes only and should be read in conjunction with the original text, which remains the only legally binding reference.

Florence, May 12, 2026
Techniconsult Group, an Italian group specialized in the Life Sciences sector, capable of supporting clients throughout the entire lifecycle of a project—from initial consulting and design, to procurement support, construction management and execution, through to start-up, commissioning, qualification and plant maintenance—today announces that it has achieved B Corp™ certification, joining a growing global movement committed to benefiting people and the planet.

Certified B Corporations are companies that meet B Lab’s high standards of social and environmental performance, transparency, and accountability. B Lab and the B Corp movement aim to accelerate behavioral, cultural, and structural change, promoting an inclusive, equitable, and regenerative economic system.

“Becoming a B Corp represents an important step in Techniconsult Group’s sustainability journey. It recognizes a commitment built over time and confirms our intention to continue integrating these principles into the way we operate.”— Pier Angelo Galligani, Co-founder & President, Techniconsult Group

This milestone comes at a time when the ongoing climate crisis and increasing social inequality continue to pose urgent challenges for the global economy. B Corp certification takes a holistic approach, assessing a company’s overall performance across key impact areas, including governance, workers, community, environment, and customers.

As part of the certification process, companies are required not only to provide evidence of their performance but also to legally embed their commitment to generating a positive impact within their corporate governance structure.

Techniconsult Group is now part of a growing global community of over 10,000 certified B Corps.

Across the five areas of the B Impact Assessment, Techniconsult Group has integrated sustainability principles into its operating model:

Governance: The Group has implemented a long-term decision-making model that integrates economic performance with social and environmental impact, supported by structured processes, measurable objectives, and transparency.

Workers: The commitment translates into continuous investment in people’s development and well-being, through ongoing training, professional growth, and a fair and inclusive work environment.

Community: Techniconsult Group operates as an active part of its ecosystem, building relationships with partners and suppliers aligned with ethical principles, and contributing to local development.

Environment: The company adopts an approach focused on reducing environmental impact through process optimization and responsible resource use, both within the Group and across client projects.

Customers: The Group builds strong, long-term relationships based on trust, transparency, and accountability, with the goal of generating value and a positive impact over time.

“We are proud to join the B Corp community, among the first engineering companies in Italy to achieve this certification. It is a choice driven by internal conviction and a journey built over time, which today allows us to be increasingly aligned with the evolution of the Life Sciences sector.”— Rosario Lo Presti, Co-founder & CEO, Techniconsult Group

About B Lab B Lab is a global network of nonprofit organizations—including B Lab Global, B Lab Europe, and B Lab Italia—working to accelerate behavioral, cultural, and structural change in order to promote an inclusive, equitable, and regenerative economic system that benefits people, communities, and the planet.

B Lab develops standards, tools, policies, and programs for businesses, and certifies companies—known as B Corps. Today, the global B Corp community includes over 1 million workers across more than 10,000 companies, operating in over 100 countries and across 160 industries.

For more information, visit bcorporation.net.

About B Lab Italia Part of the global B Lab network, B Lab Italia aims to redefine the meaning of success in business by building a community of committed companies, raising awareness of the B Corp movement, and driving change within the Italian economy.

About B Corp Certification Certified B Corps™ are companies that meet B Lab’s standards for social and environmental performance, transparency, and accountability. Built on stakeholder input, research, and established best practices, these standards form the foundation of the B Corp certification requirements, as well as B Lab’s impact management tools, and inform the network’s programs and collective action initiatives.

The B Corp Movement The B Corp movement is a global community of people committed to using business as a force for good. It works to transform the economic system—from a shareholder economy to a stakeholder economy; from concentration of wealth and power to equity; from extraction to regeneration; and from individualism to interdependence.

For further information bcorp.com

L'articolo Techniconsult Group Achieves B Corp Certification proviene da Techniconsult.

Circular Strategies in the Life Science Industry

Pier Angelo Galligani — Fri, 07 Jun 2024 07:21:58 +0000

Circularity and life cycle assessment are foundational pillars of sustainability within the pharmaceutical industry, essential for minimizing our environmental impact. This holistic approach demands a thorough examination of every stage in the life cycle of goods and materials, from raw material extraction to disposal or recycling. By embracing circularity, we aim to optimize resource use, reduce waste, and mitigate our footprint on the planet.

To effectively implement circularity principles, we must first understand the intricate web of manufacturing processes and their environmental repercussions. This includes considering inbound and outbound materials and goods, as well as solid, liquid, and gaseous effluents. Auxiliary services and functions, such as those within the supply chain and quality controls, also play a crucial role in the circularity equation.

Given the complexity of assessing environmental impacts across the entire life cycle, leveraging software tools becomes invaluable. These tools enable us to analyze a vast array of data relevant to materials and goods, facilitating informed decision-making and optimization.

In the pharmaceutical realm, circularity manifests in various domains:

Material Selection: Beginning from the design phase, prioritize reusable or recyclable materials and those sourced from renewable energy. Packaging materials, notorious for their environmental impact, should be predominantly recyclable.
Facility Design Practices: Optimize facility design to maximize reuse and recycling. This includes strategies like steam condensate reuse and closed loops for heat exchange, alongside minimizing leaks and harnessing local resources like well water.
Operational and Maintenance Practices: Implement robust waste sorting mechanisms and preventive maintenance programs to prolong the life of equipment and reduce material losses. Operator training is essential for maximizing efficiency during manufacturing processes.
Enhanced Manufacturing Process Knowledge: Utilize technologies like Process Analytical Technology to refine manufacturing processes and optimize resource use.

A significant environmental burden within pharmaceutical facilities stems from solid, liquid, and gaseous effluents. It is imperative to treat these in accordance with local regulations and adopt practices that minimize their impact. Solid waste should be recyclable wherever feasible, with exceptions for special waste requiring specific treatment. Incineration technologies can convert solid waste into a source of thermal energy, while liquid effluents should undergo purification before disposal. Gaseous emissions must be subjected to adequate treatment before release into the atmosphere, with air recirculation encouraged where compliant with regulations.

Furthermore, a comprehensive life cycle assessment should account for the decommissioning phase, aiming to minimize contamination through careful material selection during the design phase.

Achieving circularity demands interdisciplinary collaboration and expertise, promising substantial reductions in our environmental footprint over the mid- to long-term. Embracing these principles not only safeguards our planet but also ensures the sustainability of our operations in the pharmaceutical industry.

Learn more on how to obtain a sustainable facility

L'articolo Circular Strategies in the Life Science Industry proviene da Techniconsult.

Towards a greener pharmaceutical industry: Energy efficiency

Pier Angelo Galligani — Fri, 19 Apr 2024 08:44:35 +0000

Energy efficiency first is a guiding principle widely used in EU policies concerning environment and sustainability as its application may contemporary guarantee lower primary energy consumption, less energy distribution losses, reduced operational costs and decarbonization.

First, it is worth underlining what energy efficiency means. According to the EN ISO 50001:2018, energy efficiency may be defined as the ratio between an output (of performance or energy, etc.) and an input of energy. Then, the efficiency can be increased by reducing the input, increasing the output, or applying a combination of the two.

Such a concept is clear when related to machines as the energy efficiency coincides (more or less) with the engine efficiency. The latter determines the difference between input and output values.

Regarding manufacturing plants, the complexity of achieving energy efficiency increases. This is because both personnel behaviors and equipment operations can impact the plant’s energy efficiency and often, the energy consumption is not accurately aligned with actual needs.

Such an aspect may be due to insufficient metering and control systems, and consequently, operations cannot instantaneously follow energy use requirements. Moreover, manually controlled activities are hardly reproducible, and the related consumption is usually not computed. Another cause may be the oversizing of plants, machinery, and user requirements.

It should be noted that in the case of energy production systems powered by fossil fuels, increased energy efficiency promotes a reduction in CO2 emissions into the atmosphere.

From theory to practice, we report the strategy adopted to improve the energy efficiency in a green-field project related to a sterile drugs facility.

Three main measures were applied: the building envelope insulation improvement, the hot water production through a heat recovery chiller and the supply air flow rate in classified areas.

In detail, the first measure regards the building envelope insulation enhancement. The local regulation reports minimum requirements for thermal transmittance in new or renovated buildings, but they are not mandatory for manufacturing plants. However, such values are used as references in the design. This choice leads to a decrease in yearly consumption of 3% for electricity and 12% for natural gas.

The second energy efficiency improvement measure regards the heat recovery from a chiller to generate hot water feeding HVAC systems instead of installing a dedicated natural gas boiler. The benefit of this design choice is a relevant decrease in natural gas consumption, i.e.: -54% yearly. On the other hand, the heat recovery from the chiller entails a 7% increase in electricity consumption. Even if the two effects are opposed, the overall benefit is clear in terms of energy saving and, in this case, even decarbonization.

Finally, supply air flow rate decrease in classified areas is shown. This measure is composed of two different ones: the reduction during the manufacturing operations (in-operation periods) and the further attenuation in the at-rest periods.

In detail, during the design, the generally adopted method of imposing predetermined values of Air Change per Hour (ACH), based on experience and empirical considerations, is replaced by accurate calculations of required supply air flow rates and ventilation effectiveness for each area. The latter are evaluated through computational fluid dynamics (CFD) analyses for the most complex spaces and configurations.

Then, the air flow rate reduction and attenuation result as a consequence of the adopted method and do not implicate any safety or GMP risk. Such a measure determines multiple benefits: it entails not only the decrease of ventilation energy but also the reduction of energy consumption for cooling and heating since the treated air volume lowers. The energy saving per year due to this design choice accounts for 8% of the overall electricity consumption.

In summary, the reported energy efficiency improvement measures lead to a remarkable reduction in natural gas consumption and an additional decrease in used electricity. As a result, the overall saving of 32% of the annual energy consumption is obtained.

Learn more on how to obtain a sustainable facility

L'articolo Towards a greener pharmaceutical industry: Energy efficiency proviene da Techniconsult.

The contribution of CFD simulation to sustainability in the pharmaceutical industry

Pier Angelo Galligani — Thu, 28 Sep 2023 15:54:25 +0000

In the pharmaceutical industry, adoption of contamination control strategies (CCS) and the implementation of adequate quality risk management measures (QRM) are critical for organizations to guarantee product quality and safety. Computational fluid dynamics (CFD) simulation has emerged as a powerful tool to provide invaluable insights into fluid flow, heat transfer, contamination dispersion and control within the manufacturing environment.

Today, alongside GMP compliance, optimizing energy consumption and reducing the carbon footprint have become significant concerns due to the substantial ventilation airflows required for clean spaces and classified environments. By leveraging CFD simulation in HVAC design, pharmaceutical organizations can support contamination control strategies (CCS) as well as implement robust quality risk management practices, ultimately ensuring the production of safe and effective pharmaceutical products while driving sustainability initiatives.

How CFD simulation can support Contamination Control Strategy (CCS) and Quality Risk Management (QRM)

Controlling contamination is of paramount importance in pharmaceutical plants to ensure product quality, safety, and compliance with regulatory standards. CFD simulation plays a pivotal role in supporting CCS and QRM by providing a comprehensive understanding of airflow patterns, particle dispersion, and the expected performance of cleanrooms. Through accurate modeling, CFD simulation helps identify potential contamination sources, evaluate the effectiveness of ventilation systems, and assess the system’s capability to respond to possible contamination events. By visualizing airflow patterns and particle trajectories, areas with inadequate performance can be identified, leading to the implementation of targeted mitigation strategies to minimize contamination risks. Moreover, CFD simulation aids in optimizing air filtration systems, cleanroom layouts, and operational procedures to enhance overall contamination control measures.

How CFD simulation can support sustainability initiatives

Computational Fluid Dynamics (CFD) simulation offers significant advantages in optimizing airflow design and associated energy consumption in classified areas within pharmaceutical plants. By accurately modeling and analyzing the airflow, CFD allows for the reduction of energy-intensive processes while ensuring operational efficiency, thus contributing to sustainability efforts.

Reducing Energy Consumption in Classified Areas at the design condition:

CFD simulation enables the optimization of design airflow rates in classified areas, leading to substantial reductions in energy consumption associated with ventilation systems. By fine-tuning the design airflow rates, pharmaceutical plants can ensure that the necessary cleanroom conditions are maintained while minimizing unnecessary energy expenditure; this results in cost savings and reduced environmental impact.

Supporting programs for Energy Savings in non-operational periods:

Thanks to simulation process, CFD can assist in the implementation of energy-saving programs by evaluating and reducing airflow rates during non-operational and unmanned periods. In unmanned conditions, HVAC systems for classified areas can maintain required performance levels with reduced airflow rates. CFD simulation aids in anticipating the performances of HVAC systems at reduced airflow conditions, identifying areas with inadequate performance, and enabling corrective actions early at the design phase.

Reduction of ventilation energy burden:

The energy consumption for ventilation is proportional to the cube of the supplied air volume. Consequently, even limited reductions in airflow rates can lead to a substantial decrease in energy consumption for ventilation systems. Reducing ventilation contributes to economic savings but also positively impacts the overall energy consumption of utilities production systems.

Enhancing Sustainability through CFD:

By leveraging CFD simulation, pharmaceutical companies can proactively pursue sustainability goals. Optimizing airflow rates and implementing energy-saving programs aligns with environmental commitments and reduces the plant’s carbon footprint. Additionally, reduced energy consumption contributes to overall sustainability by conserving natural resources and decreasing greenhouse gas emissions.

Figure N.1 – Example
Use of CFD for the optimisation of airflow patterns in a “grade B” filling room. Case description

Problem: high quantity of air coming from the RABS and the HEPA ceiling to be returned to the HVAC system -> preliminary CFD analysis of airflow patterns inside the room -> difficulty to balance the system, risk of eddies.
Solution: Corrective actions and optimization of flows via the introduction of an additional air-wall and the sectorizing of two air-walls -> virtual balancing of the return airflow rates.

Results of CFD simulation

In general: airflow patterns after corrective actions are more even. Eddies shown in the section are eliminated and unidirectionality of air flow is much more present in the room space -> risk of back flow from floor level to critical areas (staging areas, open RABS outlets and mouse-hole) is reduced.
At the same time, this aerodynamic correction can support the reduction of room airflow rate during at rest conditions

Conclusion

CFD simulation has emerged as a powerful tool to support contamination control strategies, quality risk management, and sustainability initiatives in pharmaceutical plants. By accurately predicting fluid flow, heat transfer and contamination dispersion, CFD simulation enables organizations to make informed decisions, optimize processes, and ensure the production of safe and effective pharmaceutical products.

L'articolo The contribution of CFD simulation to sustainability in the pharmaceutical industry proviene da Techniconsult.