A thermophysical method or process for producing a biofilm without chemical additives (acids, bases, or plasticizers) or the addition of other components such as fibers or starches. The material is resistant to mechanical stress similar to paper, a natural thermal and acoustic insulator for the protection and transport of solid products, and is 100% biodegradable.
A thermophysical method or process for producing a biofilm without chemical additives (acids, bases, or plasticizers) or the addition of other components such as fibers or starches. The material is resistant to mechanical stress similar to paper, a natural thermal and acoustic insulator for the protection and transport of solid products, and is 100% biodegradable.
An implant-supported and prosthetically guided histiogenic distraction device, characterized by its control over the direction of distraction, allowing for the reshaping of a bone segment in a predetermined, desired position. This device enables the regeneration of bone tissue lost in the gingiva and maxilla due to trauma or accident. A simple device requiring a straightforward installation process, it is useful in oral and maxillofacial surgery and reconstructive implantology, offering a less invasive approach.
iofilm made from 100% natural fiber, obtained from vegetable waste such as carrots, oranges, and cauliflower. It is a 100% biodegradable material, free of chemical additives, that begins composting after five days. It can be transformed into packaging for dry foods.
The present invention relates to a device that enables the in-situ deposition of materials at different growth angles from a single evaporation source. The oblique-angle growth of thin-film materials facilitated by this device is based on physical vapor deposition (PVD) processes and is achieved by gradually varying the orientation angle of the substrate surface relative to the material flow from the evaporation source. This device allows for the modification of the growth structure of various materials at the nanoscale and microscale, opening the possibility of studying the influence of these microstructures on the mechanical, optical, thermal, electrochemical, and other properties of thin-film materials.
This device for dynamic testing of seismic isolator prototypes in a real-world environment allows for the application of uniaxial shear, compression, or a combination of both loads. The device enables controlled vertical compression and lateral deformation of the seismic isolator specimens under test. The configuration of the device’s components allows for automated testing, subjecting the specimens to successive cycles of varying or increasing amplitude in both directions until limit states are reached without the need to reposition the specimens between tests. Through the controlled application of forces and deformations via vertical compression and horizontal tension-compression mechanisms, the seismic isolator specimens are loaded and deformed in both directions, generating the actual stress conditions under service conditions as would occur during a real seismic event in a structure.
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