The present invention relates to a grown bioleather (1), which can be used in all sectors where animal skin and artificial leather are used, resembles a genuine leather both physically and optically, does not contain any chemicals, and has cellulose produced by microorganisms as its raw material and production method thereof. With the bioleather production method (100), a bioleather that can be named as vegan leather is obtained, which leather prevents climate change and environmental pollution by reducing carbon emissions and supports sustainable development and green economy. The said bioleather (1) involves a bacterial weaving process, can decompose in soil in a short amount of time, is highly environmentally friendly, flexible and has high tensile strength and high mechanical strength.

The present invention relates to a grown bioleather (1), which can be used in all sectors where animal skin and artificial leather are used, resembles a genuine leather both physically and optically, does not contain any chemicals, and has cellulose produced by microorganisms as its raw material and production method thereof. With the bioleather production method (100), a bioleather that can be named as vegan leather is obtained, which leather prevents climate change and environmental pollution by reducing carbon emissions and supports sustainable development and green economy. The said bioleather (1) involves a bacterial weaving process, can decompose in soil in a short amount of time, is highly environmentally friendly, flexible and has high tensile strength and high mechanical strength.

The present invention relates to a multi-layer shrink film comprising at least one shrink base layer and an inkjet printable layer, the latter comprising at least one cellulose-based binding agent, to methods of making such a multi-layer shrink film and of providing graphical information by means of such a multi-layer shrink film, to articles provided with such a multi-layer shrink film as well as to the use of a particular cellulose-based binding agent in the inkjet printable layer of an inkjet printable shrink film.

The present invention relates to a multi-layer shrink film comprising at least one shrink base layer and an inkjet printable layer, the latter comprising at least one cellulose-based binding agent, to methods of making such a multi-layer shrink film and of providing graphical information by means of such a multi-layer shrink film, to articles provided with such a multi-layer shrink film as well as to the use of a particular cellulose-based binding agent in the inkjet printable layer of an inkjet printable shrink film.

An interlayer structure having a cellulose ester layer for use in structural laminates is described herein. The cellulose ester layer provides rigidity and support to multilayer interlayers comprising an array of different layers. Due to the diverse properties of the cellulose ester layers, the present interlayers can be useful in producing structural laminates having high stiffness and which possess good optical clarity for a variety of applications, including outdoor structural applications.

An interlayer structure having a cellulose ester layer for use in structural laminates is described herein. The cellulose ester layer provides rigidity and support to multilayer interlayers comprising an array of different layers. Due to the diverse properties of the cellulose ester layers, the present interlayers can be useful in producing structural laminates having high stiffness and which possess good optical clarity for a variety of applications, including outdoor structural applications.

An monolithic interlayer with high stiffness and when laminated into a glass panel, the glass panel exhibits good clarity, while maintaining the processability of a polyvinyl acetal, such as polyvinyl butyral resin used to make the monolithic interlayer. The monolithic interlayer comprising a polymer blend of: (A) polyvinyl acetal (e.g. PVB); and (B) one or more cellulose esters.
The polymer blend increases the structural strength to the monolithic interlayer by increasing the E modulus of the monolithic interlayer while optionally maintaining good optical clarity.

An monolithic interlayer with high stiffness and when laminated into a glass panel, the glass panel exhibits good clarity, while maintaining the processability of a polyvinyl acetal, such as polyvinyl butyral resin used to make the monolithic interlayer. The monolithic interlayer comprising a polymer blend of: (A) polyvinyl acetal (e.g. PVB); and (B) one or more cellulose esters.
The polymer blend increases the structural strength to the monolithic interlayer by increasing the E modulus of the monolithic interlayer while optionally maintaining good optical clarity.

A formed body includes a base material, an adhesive layer, and a cellulose acylate film. The base material is formed of a thermoplastic resin and is in the form of a transparent sheet. The adhesive layer bonds the base material and the cellulose acylate film. The cellulose acylate film has a thickness in a range of 15 m or more and 100 m or less, and is formed of cellulose acylate including an ester oligomer or a sugar ester derivative.

An interlayer structure having a cellulose ester layer for use in structural laminates is described herein. The cellulose ester layer provides rigidity and support to multilayer interlayers comprising an array of different layers. Due to the diverse properties of the cellulose ester layers, the present interlayers can be useful in producing structural laminates having high stiffness and which possess good optical clarity for a variety of applications, including outdoor structural applications.