An electrical junction box includes a housing that defines an internal space. The housing has a front, which is open. A buss bar is coupled to the housing and is positioned in the internal space. A plurality of connectors is coupled to the buss bar and extends through a respective opposing side of the housing. A plurality of couplers is coupled to the buss bar. The couplers are positioned on a front face of the buss bar. The connectors are configured for insertion of wires, such that the wires are coupled to the buss bar and the buss bar is coupled to an electrical circuit. The couplers are configured for insertion of wiring that is coupled to an electrical device, such as a switch, light, fan or outlet. The wiring is coupled to the buss bar and the electrical device is coupled to the electrical circuit.

Methods and devices for selectively presenting a user interface in a dual screen device. More particularly, the method includes providing a gallery for the dual screen device. The gallery can present one or more images in a user interface. The gallery user interface can adapt to changes in the device configuration. Further, the gallery can display images or videos in the various configurations.

Methods and devices for selectively presenting a user interface in a dual screen device. More particularly, the method includes providing a gallery for the dual screen device. The gallery can present one or more images in a user interface. The gallery user interface can adapt to changes in the device configuration. Further, the gallery can display images or videos in the various configurations.

An enclosure for a portable electronic device includes a titanium substrate having a textured surface that includes peaks separated by valleys, where the textured surface is characterized as having (i) an Sdq (root mean square gradient) that is greater than 0.2 micrometers, and (ii) a gloss value that is greater than 90 gloss units as measured at 60 degrees by a gloss meter.

An enclosure for a portable electronic device includes a titanium substrate having a textured surface that includes peaks separated by valleys, where the textured surface is characterized as having (i) an Sdq (root mean square gradient) that is greater than 0.2 micrometers, and (ii) a gloss value that is greater than 90 gloss units as measured at 60 degrees by a gloss meter.

A method of manufacturing a casing of an electronic device including the following steps is provided. A metallic housing is provided, wherein the metallic housing has an inner surface and an outer surface opposite to the inner surface and includes a back region and at least one side region. At least one gap, a plurality of apertures and a non-conductive layer are formed on the inner surface of the metallic housing, wherein the apertures is formed on a surface of the at least one gap, part of the non-conductive layer is formed in the at least one gap and extended from the back region to the at least one side region, and part of the non-conductive layer is extended into the apertures. Part of the metallic housing is removed for exposing part of the non-conductive layer, thereby forming a plurality of non-conductive spacers located in the at least one gap.

A method of manufacturing a casing of an electronic device including the following steps is provided. A metallic housing is provided, wherein the metallic housing has an inner surface and an outer surface opposite to the inner surface and includes a back region and at least one side region. At least one gap, a plurality of apertures and a non-conductive layer are formed on the inner surface of the metallic housing, wherein the apertures is formed on a surface of the at least one gap, part of the non-conductive layer is formed in the at least one gap and extended from the back region to the at least one side region, and part of the non-conductive layer is extended into the apertures. Part of the metallic housing is removed for exposing part of the non-conductive layer, thereby forming a plurality of non-conductive spacers located in the at least one gap.

One example provides a method of manufacturing. The method comprises printing multiple layers comprising a metal material by an additive manufacturing technique, wherein each of the multiple layers comprises an array of cavities each having a cross-section of a polygon; and assembling at least two of the multiple layers to form an article having an array of three-dimensional hollow cells collectively having a honeycomb structure.

One example provides a method of manufacturing. The method comprises printing multiple layers comprising a metal material by an additive manufacturing technique, wherein each of the multiple layers comprises an array of cavities each having a cross-section of a polygon; and assembling at least two of the multiple layers to form an article having an array of three-dimensional hollow cells collectively having a honeycomb structure.

An electronic device and a framework assembly for the same are provided. The electronic device includes a base structure, an antenna module and a first decorative board. The base structure has a first surface and a second surface corresponding in position to the first surface. The base structure includes a base body, a receiving slot disposed on the base body, and a first positioning portion disposed on the receiving slot. The antenna module is disposed in the receiving slot of the base structure and includes a mount element and an antenna disposed on the mount element. The mount element includes a second positioning portion corresponding in position to the first positioning portion. The first decorative board is disposed on the first surface of the base structure.