Abstract: An energy efficient film comprising of first and second substrate layers and microstructures positioned between the first and second substrates is provided. The microstructures are positioned between the first and second structures such that a vacuum environment is created between the first and second substrates. In one embodiment, the insulating film includes a first substrate, a second substrate, and a plurality of microstructures positioned between the first substrate and the second substrate, such that a vacuum environment is created between the first and second substrates and within each microstructure cell, individually. Preferably, the plurality of microstructures is a polygonal cellular network positioned between a first transparent substrate and a second transparent substrate. A gasket may be provided on one or both of the first or second substrates. The gasket may also be provided on outer edges of the first and/or the second substrate.

Abstract: An energy efficient film comprising of first and second substrate layers and microstructures positioned between the first and second substrates is provided. The microstructures are positioned between the first and second structures such that a vacuum environment is created between the first and second substrates. In one embodiment, the insulating film includes a first substrate, a second substrate, and a plurality of microstructures positioned between the first substrate and the second substrate, such that a vacuum environment is created between the first and second substrates and within each microstructure cell, individually. Preferably, the plurality of microstructures is a polygonal cellular network positioned between a first transparent substrate and a second transparent substrate. A gasket may be provided on one or both of the first or second substrates. The gasket may also be provided on outer edges of the first and/or the second substrate.

Abstract: A simple and innovative process for manufacturing a high performance mechanical polarizing device is provided. The invention utilizes an inexpensive, high output production process where a transparent film substrate is coated with a non-transparent layer by deposition or other wet or dry method. Then a photoresist or a nano-imprint lithography process is used to overlay the non-transparent coated film with a pattern. The exposed non-transparent material is then removed by means of acid or base etching or the use of other mechanical or nano-technology removal methods. The photoresist is then removed and a protective layer may then be applied to the polarizer substrate. According to another embodiment, nano-imprinting techniques are used to prepare the polarizer substrate. The process may be automated in one or more embodiments, and lends itself to a high speed production manufacturing line, utilizing roll-to-roll, sheet fed or other methods of automated manufacturing.

Abstract: A simple and innovative process for manufacturing a high performance mechanical polarizing device is provided. The invention utilizes an inexpensive, high output production process where a transparent film substrate is coated with a non-transparent layer by deposition or other wet or dry method. Then a photoresist or a nano-imprint lithography process is used to overlay the non-transparent coated film with a pattern. The exposed non-transparent material is then removed by means of acid or base etching or the use of other mechanical or nano-technology removal methods. The photoresist is then removed and a protective layer may then be applied to the polarizer substrate. According to another embodiment, nano-imprinting techniques are used to prepare the polarizer substrate. The process may be automated in one or more embodiments, and lends itself to a high speed production manufacturing line, utilizing roll-to-roll, sheet fed or other methods of automated manufacturing.

Abstract: An adjustably opaque window includes external and internal panes, an active optical material layer, passive optical material layers, and shock absorbing layers. The external pane and the internal pane provide a cavity between them. The optical material layers and the shock absorbing layers are positioned in the cavity. The optical material layers are sandwiched and supported by the shock absorbing layers. The interval between the external and internal panes can vary from about one to about two millimeters, and at least one of the internal and external panes is adapted to be attached to a substantially smooth surface. The shock absorbing layers may include first and second shock absorbing layers, and the first and second shock absorbing layers may be disposed at either side of the light transmission control layer or both are disposed at a same side of the light transmission control layer.

Abstract: An adjustably opaque window including an external pane, an internal pane, a light transmission control layer and a shock-absorbing layer is provided. The external pane and the internal pane provide a cavity between them, and the light transmission control layer and the shock-absorbing layer are positioned in the cavity. The shock-absorbing layer is a flexible sheet that supports and protects the light transmission control layer. The light transmission layer consists of liquid crystal cells. The transmission ratio of the cells can be controlled variably.

Abstract: An adjustably opaque film, including substantially flexible/transparent confining films and light transmission control layers, is provided. The inner surfaces of the first and second confining films form a confined space layer with substantially constant thickness. The adjustably opaque film is applied on a window panel which is already installed like a regular window pane on a building or an automobile. The film is not sandwiched between two window panels or panes. The film is adapted to be applied on a surface of window panels. The film is substantially flexible enough to be able to be easily handled and applied on the window panel in conventional construction site conditions. The interval between the first and second confining films is from about one (1) millimeter to about two (2) millimeters, which is an important point along with the flexibility.

Abstract: An adjustably opaque window including an external pane, an internal pane, a light transmission control layer and a shock-absorbing layer is provided. The external pane and the internal pane provide a cavity between them, and the light transmission control layer and the shock-absorbing layer are positioned in the cavity. The shock-absorbing layer is a flexible sheet that supports and protects the light transmission control layer. The light transmission layer consists of liquid crystal cells. The transmission ratio of the cells can be controlled variably.

Abstract: An adjustably opaque window including an external pane, an internal pane, a light transmission control layer and a shock-absorbing layer is provided. The external pane and the internal pane provide a cavity between them, and the light transmission control layer and the shock-absorbing layer are positioned in the cavity. The shock-absorbing layer is a flexible sheet that supports and protects the light transmission control layer. The light transmission layer consists of liquid crystal cells. The transmission ratio of the cells can be controlled variably.