Vandersanden Opens Pirrouet Production Facility in Lanklaar with New Brick Press from Rekers (Part 2)

The decision to commission Rotho for the CO₂ curing chambers was also based on Rotho’s expertise in curing concrete products as well as in drying ceramic products like roof tiles and bricks. Knowledge from both disciplines is required to achieve optimal carbonation of Pirrouet facing bricks. This approach is based on the fact that CO₂ must diffuse into the product to react with the mineral steel residue. This also requires the evaporation of some of the mixing water and the creation of capillaries to transport CO₂ into the product’s interior. Considering that high CO₂ concentrations can be harmful or fatal to humans, several quality-compliant requirements can be defined, which are essential for CO₂ curing:

1 CO₂ Supply:

CO₂ supply is the central element in carbonating Pirrouet facing bricks. Precise dosing of CO₂ is crucial for a stable process, as a closed system can react with rapid pressure fluctuations due to too much or too little CO₂, potentially triggering safety systems and creating an unmanageable process. A CO₂ control system was developed to automatically supply the necessary CO₂ quantities to the process.

2 Ventilation System:

Ventilation technology is essential to ensure that all products are sufficiently supplied with CO₂. Without enough CO₂, products may not achieve the necessary strength, resulting in possible failure in use. Consistent product quality requires an even distribution of CO₂ across all products in the chambers. This is achieved by the installation of special nozzle walls that ensure uniform treatment of all Pirrouet facing bricks throughout the chamber’s depth and height.

3 Closed Carbonation Process:

Normally, convective drying occurs in an open process, with warm, dry air introduced and colder, humid air discharged to the environment. However, with high CO₂ concentrations, a significant portion of CO₂ would be vented with the moisture, reducing CO₂ available for carbonation and releasing more CO₂ back into the atmosphere. To prevent these effects, carbonation must occur in a closed process. The climate chamber can be time-controlled via corresponding curing programmes stored in the process control.

4 Construction and Door Sealing:

National workplace standards for permissible CO₂ concentrations require high sealing standards for the chambers and ventilation systems. Rotho’s Pro Carbon Cure system uses the self-developed, patented Quatro structure, a self-supporting sheet metal wall system that achieves the highest seal class per DIN EN 1507. A significant advantage is that connection elements, like pipes, flanges, and measuring ports, are welded firmly and tightly into the walls. Such tightness is simply unachievable with standard sandwich panels.

5 Safety Devices:

CO₂’s harmful effects on human health necessitated a preliminary HAZOP analysis. This analysis systematically examined both hazards and operational capability to ensure high safety for personnel, equipment, the environment and functionality. Based on this risk analysis, Rotho developed safety features like a leak monitoring system for continuous sealing checks, multi-stage pressure monitoring, and SIL-compliant safety valves, among others. Ensuring a safe facility was a primary focus for all project participants.

6 Control and Regulation:

Coordinating all upstream and downstream systems, such as CO₂ supply, CO₂ monitoring in the curing hall, and ventilation systems, is crucial to the successful start-up of Pro Carbon Cure chambers. Rotho’s control system acts as a central management system to process all these signals into a safe and reliable operation.

Rotho is making an important contribution to storing large quantities of carbon dioxide with its Pro Carbon Cure technology for carbonating Pirrouet bricks - the first bricks with a negative carbon footprint.

Unloading Device Including rack exchange Car (Buffer function)

The unloading device operates similarly to the loading device on the wet side. Additionally, the dry side is equipped with a double rack on the rack exchange car to buffer the cured products. This allows the finger car to deposit cured products while the unloading device retrieves products from the other rack. Once the first rack is emptied, the rack exchange car shifts so the unloading device can immediately unload products to the dry side. This setup is a smart and cost-effective buffering solution compared to conventional designs using additional dynamic buffers or a second (double) lowerator.

Dry Side on two levels

Another innovation is the two-level setup of the dry side. The unloading device is connected to a board conveyor, specifically a belt conveyor, which conveys the boards with cured products to another cross-belt conveyor. Along this conveyor, a product compactor detaches products from the board, improving cycle time efficiency. Using an elevator, the boards are raised to a second level at 2,500 mm. Behind the elevator, there is also a sorting area for lab bricks, allowing cured products to be taken for laboratory testing.

On the second level, a walking beam conveyor conveys the boards towards two product transfer grabs arranged in sequence. Each of these product transfer grabs taking two rows of pushed-together products and places them onto two parallel product conveyor lines, also installed at a height of 2,500 mm.

These two parallel conveyor lines provide the advantage of allowing different products to be individually directed to a finishing line. Later in the packaging process, it is possible to recombine and merge products from both conveyors, enabling a higher degree of customization and flexibility. Furthermore, the two-level design creates clear pathways for movement around the product conveyors, enabling quick access between the operator and laboratory rooms. Identical components are used for all product-handling machines on the dry side, simplifying spare parts inventory and promoting efficient maintenance and repair.

Ergonomic Product Inspection

Despite limited space in the facility due to the significant increase in delivery volumes during the project, all parties involved maintained a strong focus on providing adequate space and ergonomic platforms for effective product inspection and system monitoring.

For manual product inspection, the product conveyors allow ample room at the attached robotic packaging station. Numerous access points and generously sized maintenance platforms ensure all areas remain accessible, allowing operators to move safely and efficiently within the facility.

Flexible Robotic Packaging line

The packaging robot creates two half-packs made up of facing bricks from both product conveyors. This configuration means the brick packages consist of corner and standard bricks. The robot picks up a layer of bricks and stacks it on shipping pallets, which have been previously separated and positioned on a horizontal pack conveyor carousel by another robot. A third robot with a vacuum unit applies intermediate layers of sheets between the individual brick layers. Robotic packaging provides high flexibility and customization options for individual brick packages. Furthermore, the packaging robots are space-efficient and require minimal maintenance, with excellent accessibility via maintenance platforms and walkways.

Horizontal pack conveyor carrousel and Packaging Machines

After the product packages are created, the half-packs are transported through the packaging machines by a horizontal pack conveyor type carrousel system with multiple frequency-controlled drive segments. The half-packs undergo vertical strapping and a shrink-wrapping machine before being combined into a full pack. This complete product pack out of two half packs then passes through a second vertical strapping process. Additionally, a real-time labeling system affixes all relevant product information to the side of the package during the conveyor process. The horizontal pack conveyor carrousel was designed with an outdoor storage capacity of up to 10 packages.

System Safety

System safety meets the latest standards, incorporating an IO check, a safety matrix, and a key transfer system for cleaning and maintenance activities to ensure a power-off state in each safety zone. The safety zones are enclosed by protective fences and enhanced with light curtains and barriers in the product inspection areas.

Maintenance platforms and generously sized access gates ensure excellent accessibility to individual system components and safety zones.

Rekers Control System Including Product Tracking 4.0 – A New Approach to Data Collection and Processing

The Rekers control system for the production facility at site Lanklaar offers simple and intuitive operation of the entire plant, including a database for user management, product/component management, recipe and component control, batch logging for all mixtures, and much more. The uniform operating concept with standardized electronic, programming, and visualization systems ensures straightforward and intuitive plant operation.

Data collection and processing are increasingly critical for both machine manufacturers and producers. To optimize production planning and management, the control system is integrated with Vandersanden’s ERP (Enterprice Resource Planning) system, allowing traceability of analyzed data via labeling codes. This places Vandersanden a step ahead of other facilities in terms of traceability.

Simplified Spare Parts Management with Online Access

Vandersanden is also well-equipped for spare parts management with Rekers’ personalized online access. Online, each machine can be viewed as a 3D model, simplifying part selection. The total number of installed parts can be quickly and easily determined to facilitate spare parts inventory. The online access also provides documentation and tracks maintenance intervals for each machine component and the entire facility.

Pilot Plant Sets a Benchmark

The pilot plant centered around the brick press represents not only a future-oriented investment but also a landmark in sustainable and climate-friendly production processes for facing bricks.

Thanks to innovative process technology, it is possible to produce facing bricks that capture atmospheric CO₂ while maximizing energy efficiency. Vandersanden follows a holistic sustainability approach, beginning with a power supply from ist own photovoltaic and wind energy sources. This continues with the production of facing bricks that can be manufactured with significantly lower energy and absorb up to 60 kg of CO₂ per ton. During production, another focus is on implementing quiet processes without heavy use of hydraulic oils. The advantages of this facility are further rounded out by its employee-friendly environment. The bright production hall includes a comprehensive safety concept, efficient layout with short paths, ergonomic working conditions, and excellent accessibility to safety zones and system components for user-friendly maintenance.

Through this successful collaboration with Rekers GmbH, Vandersanden makes a significant environmental contribution while setting its sights on its goal of becoming completely CO₂-neutral by 2050.

Vandersanden selected Rekers because of the shared corporate philosophy: innovative machine technology for the highest and future-oriented product requirements combined with maintenance-friendly machine access. Rekers considers not only the machinery and the final product but also user-friendly operation and energy-saving equipment for the future. This alignment, along with quick and straightforward communication, convinced Vandersanden to partner with Rekers in bringing the innovative Pirrouet production facility to success in Lanklaar.

Further project participants

Maschinenfabrik Gustav Eirich GmbH & Co. KG, Hardheim (Germany), has delivered Eirich R24 (2,250 litres) and RV12 (500 litres) intensive mixers for core and face mix as well as the EL5 profi plus laboratory mixer are now used in the new Vandersanden production facility. The result: the necessary material disintegration due to the high specific mixing energy guarantees excellent production and products.

Eng. Luca Cellini from MCT Italy, another Vandersanden project partner, added: Vandersanden is not only one of the largest, but also one of the most sustainable family-owned brick and pavers producers in Europe. Craftsmanship, co-creation, innovation and sustainability are the keywords of their approach. MCT Italy and Vandersanden ambitions are very high: aim to be completely CO₂-neutral by the year 2050. To achieve that goal, MCT Italy partnered with Vandersanden for specific equipment in order to render the processes, production methods and factory more sustainable. But that’s not all: by developing new, innovative products, Vandersanden contributes to reducing raw material usage, energy consumption and CO₂ emissions.