The complete sensXPERT product solution Altogether more powerful
Features built for industry 4.0
In-mold dielectric analysis data
Tap into sensXPERT’s powerful in-mold dielectric analysis data for an unparalleled insight into material behavior in real time. Understand what’s happening inside the mold and achieve dynamic control over your manufacturing process.
With sensXPERT, you can now plug into and easily utilize vast amounts of live data from multiple sources around and inside your mold, so as to benefit from a more holistic and transparent view of your entire process in real time.
Process optimization in real time
By leveraging real time material characterization and data analytics, sensXPERT uses advanced AI to achieve process optimization like never before. Take full control of your process, and unlock a new level of productivity and sustainability.
Materials supported by sensXPERT
With thermosets, sensXPERT focuses on chemical reactions, the so-called “curing”, and material changes during molding. The versatility of dielectric signals – which are in direct material contact during molding – allows sensXPERT to capture in-process material behavior. This includes mixing ratio effects and the effects on curing – that conventional DSC (Differential Scanning Calorimetry) or DMA (Dynamic Mechanical Analysis) techniques cannot capture. sensXPERT is experienced in successfully working with a wide range of thermosets, from epoxies, polyurethanes, phenolics to unsaturated polyesters.
Challenges when using thermosets:
The manufacturing of thermoset composites presents several challenges due to factors such as the utilization of novel resin formulations and the chemical reactions involved in combining reinforcements and fillers. Additionally, there is a need for faster reactions and shorter cycle times, and the process must accommodate environmental variations and meet the unique specifications of the component being produced.
How sensXPERT solves this challenge:
sensXPERT follows the chemical reaction of the material during molding, in order to link design, manufacturing, digitalization, and quality control.
Automotive & e-mobility: semiconductor encapsulation, e-motor components, gear housing, electric power trains, lightweight structural components, and applications requiring low vibrations, low noise and improved heat dissipation.
Aerospace & Defense: composite fuselage sections, frame structural reinforcements, and rear fuselage.
Electrical, building, and construction: construction equipment panels, heat shields, electric enclosures, load breakers, disk breakers, and pipes and sewer rehabilitation using UV light liners.
Renewable energy: wind turbine structural components, heat shields or encapsulation, frames for silicon panels, roof tiles and electrical enclosures used for solar energy.
Challenges when using thermosets: In terms of thermoplastics, sensXPERT focuses on detecting phase changes during melting and crystallization, as well as the glass transition temperature and other relevant parameters.
Challenges when using thermoplastics:
Manufacturing that uses thermoplastics is confronted with numerous obstacles, such as stiff competition and cost reduction pressures. The integration of new blends and compound formulations, alongside the inclusion of pre- and post-consumer recycled materials, each with their intricate thermal histories and compositions, presents additional difficulties. Furthermore, environmental factors exert a considerable influence, and the material’s behavior inside the mold is not yet fully comprehended.
How sensXPERT solves this challenge:
sensXPERT aims to track the thermoplastic material throughout the molding process by integrating processing, material science, and digitalization to minimize manufacturing scrap and quality control complications. Particularly with sensXPERT’s Dielectric Sensors, various manufacturing processes such as injection molding and its variants, primary recycling, extrusion, blending, primary and secondary recycling, and compounding can all reap significant benefits. We are currently focussing on the technical applications of polyamides and their variations, such as aramids, nylon, and Kevlar and primary and secondary recycling with polyethylene (PE) and polypropylene (PP) and support molders. The challenge here is to ensure a stable manufacturing process.
Automotive & e-mobility: transmission parts, fuel tanks, lubricant tanks, and parts that provide insulation, periodic fatigue resistance and wear resistance.
Electrical, building, and construction: electrical tool housings, escalator handrails.
Primary recycling: extrusion of pre-consumer or pure polymer streams.
Secondary recycling: sorting polymer waste streams, reducing the size of the polymer waste, and then extruding the material.
Challenges when using thermosets: Like thermosets, sensXPERT concentrates on chemical reactions, the so-called “vulcanization”, and material alterations during molding. The adaptability of dielectric signals in direct contact with the material during molding, enables sensXPERT to record the material’s behavior during processing. This includes the impact of mixing ratios and vulcanization – which conventional DSC (Differential Scanning Calorimetry) or DMA (Dynamic Mechanical Analysis) techniques cannot detect. sensXPERT has extensive experience with nitrile rubber (NBR), hydrogenated nitrile butadiene (HNBR), ethylene propylene diene terpolymer (EPDM), fluoroelastomer (FKM) and liquid silicone rubber (LSR).
Challenges when using elastomers:
The production of elastomer products entails numerous obstacles. Firstly, there’s the complex nature of the chemical reaction to consider – particularly when it is combined with a high filler content. Another potential challenge is the uneven mixing process used to produce pre-vulcanized elastomers. Finally, it’s also worth mentioning the effects of unforeseen processing and environmental fluctuations on the finished product’s required specifications.
How sensXPERT solves this challenge:
sensXPERT helps manufacturers optimize their reaction injection molding (RIM) and extrusion processes, including variations of these specific manufacturing processes. It is important to remember that our portfolio continues to expand, especially as we strive to follow the chemical reaction of the component during molding, linking design, manufacturing, digitalization, and quality control.
Automotive & e-mobility: seals, gaskets, o-rings, pipes, hoses, vibration damping applications, and bushings.
Electrical, building, and construction: load breakers, cords, tubing, power transformers, and parts that provide electrical and thermal insulation/damping.
Manufacturing processes that can use sensXPERT
Reaction Injection Molding
A low-pressure, closed-mold process capable of producing highly complex 3D (rigid or elastomeric) products. Most commonly used for thermoplastics, but can also be used to manufacture products made from thermosets or elastomers.
It is a rapid, dynamic process, and therefore benefits from sensXPERT’s almost immediate response to any potential deviations.
Resin Transfer Molding
This closed-mold system produces complex 3D products, with high quality surfaces, using liquid thermoset or in-situ polymerizing thermoplastic resins.
External factors, such as the storage of raw materials, thermal history, varied mixing ratios, process instabilities etc. can lead to unforeseen deviations in curing behavior – which sensXPERT detects in advance.
A fast-cycling, closed-mold process which uses high pressure to form products using thermosets, thermoplastics or elastomers. Its raw materials are supplied in either sheet or bulk form. This includes materials containing fibers, such as SMC, BMC, GMT, and Organosheets. In terms of using thermosets, the process moves very quickly, and therefore benefits from sensXPERT’s real-time response to any potential deviations.
As for thermoplastics and elastomers, extraneous external factors can have unforeseen effects on curing. In this scenario, sensXPERT is perfectly placed to detect these deviations in advance.
A method for curing fiber-reinforced composite materials in a sealed, pressurized vessel, the autoclave. The process involves applying heat and pressure to the composite material to allow the resin to cure and bond the fibers together.
It is commonly producing high-performance parts with excellent mechanical properties. As with Resin Transfer Molding, external factors can lead to unforeseen deviations in the curing process – which sensXPERT detects in advance.