A module includes a first partial housing and a second partial housing, wherein the first partial housing and the second partial housing together form a recess, a circuit board disposed in the recess; and an encapsulation mass, which closes the recess. A material from which the first partial housing is manufactured and a material from which the second partial housing is manufactured have a difference in thermal expansion coefficients that is at most 10% of the largest value of the two thermal expansion coefficients, the first partial housing includes a sealing structure and the second partial housing includes a counter-sealing structure, and at least one of the sealing structure and the counter-sealing structure is configured to extend into the other of the sealing structure and the counter-sealing structure.

A gimbal remote controller includes a press key, a sensor disposed below the press key for acquiring an operation state of the press key, and a controller electrically coupled to the sensor and configured to send a gimbal control signal in accordance with the operation state of the press key.

A device includes a display and a housing. The housing surrounds the display and has four corners defining portions of an exterior surface of the device. The housing includes a first housing segment defining at least part of a first corner of the four corners and configured to operate as an antenna; a second housing segment defining at least part of a second corner of the four corners; and a third housing segment defining at least part of a third corner of the four corners. The third corner forms part of the housing diagonally opposite the second corner. The housing further includes a non-conductive housing component that structurally couples the first housing segment to another portion of the housing.

Disclosed herein is a display apparatus having high quality and high gloss. The display apparatus includes a display module which keeps a display panel on which an image is displayed in a curved surface state, a driving unit provided at a rear side of the display module, and a cover which accommodates the display module and the driving unit and forms an exterior of the display apparatus, wherein the cover is injection molded, and includes a first cover which is disposed in front of the display module and is provided to have the same curvature as that of the display panel, and a second cover which is disposed at the rear side of the display module, is coupled with the first cover, simultaneously accommodates the display module and the driving unit, and is formed to have a curvature which is different from that of the display panel.

A peripheral wall includes a first peripheral wall edge portion and a second peripheral wall edge portion, which are disposed on a case member bottom surface so as to be distant from each other. A connector member main unit is disposed in a space between the first and second peripheral wall edge portions. A peripheral wall groove, which is open toward the connector member main unit, is disposed in each of the first and second peripheral wall edge portions. A bottom surface of the peripheral wall groove is inclined with respect to the case member bottom surface. A base plate groove is disposed on the bottom surface of the case member. A seal material is filled into the space formed between each of an inner surface of the peripheral wall groove and an inner surface of the base plate groove, and the connector member.

Each knuckle is molded in and/or around a coupling structure that is either welded to or is an integral part of the section. The coupling structure can be a bracket that is welded to an inner surface of a section, and the bracket is constructed to have a cross-section that minimizes capacitance. In one embodiment, a first bracket can be welded to a first conductive section, and a second bracket can be welded to a second conductive section. A knuckle constructed from an insulating material that is overmolded within and around the first and second brackets such that the first and second conductive sections are coupled together. The first and second conductive sections and their respective brackets are spaced a predetermined distanced apart, thereby ensuring the conductive sections are electrically isolated.

Welding of transparent material in electronic devices. An electronic device may include an enclosure having at least one aperture formed through a portion of the enclosure. The electronic device may also include a component positioned within the aperture formed through the portion of the enclosure. The component may be laser welded to the aperture formed through the enclosure. Additionally, the component may include transparent material. A method for securing a component within an electronic device may include providing an electronic device enclosure including at least one aperture, and positioning a component within the aperture formed through the enclosure. The component positioned within the aperture may include a transparent material. The method may also include welding the component to the electronic device enclosure.

The invention relates to a method (5) for producing a housing (1) for electronics that are used to control an electric motor, wherein the housing (1) is formed by a first housing element (30) and a second housing element (40). According to the invention, the housing elements (30, 40) are composed of aluminum or an aluminum alloy. Furthermore, at least one of the housing elements (30, 40) is created by means of a die-casting method (52). The housing elements (30, 40) are connected to each other tightly, in particular in a fluid-impermeable manner, by means of welding (60).

An electrical module contains at least one electrical component which is accommodated in a module housing. The module housing has at least two housing parts which lie one on the other and, on their own or together with one or more further housing parts of the module housing, delimit the interior of the module housing. There is at least one adhesive layer between the two housing parts, the adhesive layer adhesively bonding the two housing parts to one another.

An enclosure assembly for enclosing an electronic controller. The enclosure assembly comprises a housing having a plurality of cavities formed therein for receiving electrical components of the electrical controller. The enclosure assembly further includes an over-molded part formed from an elastic material that lines at least a portion of each cavity. The over-molded part reduces the effect of deceleration forces on the electrical component that is received in the cavity thereby protecting it from damage. The over-molded part includes a retention feature that locates the over-molded part within the cavity and secures it to the enclosure assembly. An interference fit is provided between the over-molded part and the electrical component received in the cavity.