Disclosed herein is a method of manufacturing an interior material, which can implement various and distinct light emission effects by disposing a light-blocking layer configured to block light emitted from a light source on a wood layer or transparent film and then allowing the component of the transparent film to fill lighting grooves formed by laser-etching. Since a tape configured to support an island is employed, stable manufacturing is possible throughout an overall process.

Disclosed herein is a method of manufacturing an interior material, which can implement various and distinct light emission effects by disposing a light-blocking layer configured to block light emitted from a light source on a wood layer or transparent film and then allowing the component of the transparent film to fill lighting grooves formed by laser-etching. Since a tape configured to support an island is employed, stable manufacturing is possible throughout an overall process.

Products and devices are described for displaying a visible marker on a screen. Density patterns create the visible marker. The present disclosure also describes methods for manufacturing or displaying the visible marker on the screen.

The invention relates to a material for facing of buildings and premises. The technical result of the proposed invention is expanding the arsenal of technical tools that allow you to apply images with stereoscopic and dynamic display. The technical result is achieved by decorative tile with stereoscopic and dynamic display, including: a front protective transparent plate, which has an external and internal side; an end protective layer; a transparent film; a rear protective layer, which has an external and internal side; a stereoscopic image; a lenticular sheet located above stereoscopic image, wherein: the front protective transparent plate its inner side is connected to a transparent film, and its edges is connected with the end protective layer which, in turn, is connected to the rear protective layer, the rear protective layer with its internal side is connected with the stereoscopic image, above which it is located a lenticular sheet, where between the mentioned lenticular sheet and the transparent film there is an air gap, which provides a stereoscopic and dynamic display of the stereoscopic image, wherein the mentioned transparent film provides additional strength to the mentioned protective transparent plate and UV protection to the stereoscopic image, and the front protective transparent plate, the end protective layer and the rear protective layer form a single sealed protective housing, in which the mentioned stereoscopic image, transparent film and lenticular sheet are located.

A thermally induced revealing decorative device has a non-opaque, or partially non-opaque, container with a matrix at least partially filling the container. A warming mechanism is used to heat this matrix, which has thermochromic properties, such that when sufficiently warmed it becomes transparent or translucent. At least one decorative item is located within, and completely encompassed by the matrix. When the matrix is cooled, it is opaque and the decorative item is hidden, but when the matrix is heated such that it becomes transparent/translucent, the decorative item is revealed.

A decorative stone panel is provided, which comprises a natural stone panel (1), a ceramic tile (4), a light source (2) and curable transparent adhesive resin (3). The ceramic tile (4) is bonded to the inner surface of the natural stone plate (1). Counter-relies (9) are provided on the inner surface of the natural stone plate (1). The stone thickness at the bottom of the counter-reliefs (9) is 1 mm to 3.5 mm. The counter-reliefs (9) form a counter-relief figure. A cavity is provided between the counter-reliefs (9) and the body of the ceramic tile (4). The light source (2) is provided within the cavity. The cavity is also filled with curable transparent adhesive resin (3) on the side of the counter-reliefs (9) The decorative panel has good light transmitting properties and the light-transmitting surface is less prone to damage.

A composite stone panel (1) is provided. The composite stone panel (1) comprises a front panel and a backing panel. The back of the front panel comprises a counter-relief image (11) filled with a light-transmitting reinforcing filler and is attached to the backing panel. The backing panel comprises a light source (6) or an opening for receiving the light source (6). The light source (6) or opening is positioned to transmit light towards the counter-relief image (11). A relief (3) is then formed at the front of the composite stone panel (1). The relief (3) is positioned opposite to the counter-relief image (11).

A composite stone panel (1) is provided. The composite stone panel (1) comprises a front panel and a backing panel. The back of the front panel comprises a counter-relief image (11) filled with a light-transmitting reinforcing filler and is attached to the backing panel. The backing panel comprises a light source (6) or an opening for receiving the light source (6). The light source (6) or opening is positioned to transmit light towards the counter-relief image (11). A relief (3) is then formed at the front of the composite stone panel (1). The relief (3) is positioned opposite to the counter-relief image (11).

A decorative product includes a decorative layer containing nickel, chromium, and molybdenum as constituent components. The molybdenum content in the decorative layer is 50 atm % or less. The total content of nickel, chromium, and molybdenum in the decorative layer is 95 atm % or more.

In some aspects, graphic layers for depicting a visible representation of an image along a surface of a photovoltaic module can include a plurality of substantially opaque isolated regions; and at least one substantially transparent contiguous region surrounding the substantially opaque isolated regions, wherein an outer surface of the at least one substantially transparent contiguous region comprises a matte surface finish.