A mobile phone may include an enclosure defining an internal volume, the enclosure including a front cover formed from a transparent material and defining a front exterior surface, a rear cover formed from a glass material and defining a rear exterior surface, and a housing component defining a side exterior surface. The mobile phone may include a circuit board assembly within the internal volume. The circuit board assembly may include a circuit board, a circuit component coupled to an exterior surface of the circuit board, and a cowling coupled to the circuit board and covering the circuit component, the cowling having a thickness less than about 0.5 mm and including a base structure formed from an aluminum alloy having a thickness less than about 0.4 mm and a thermally conductive structure positioned over the base structure and configured to dissipate heat.

A mobile phone may include a display, an enclosure enclosing the display and including a front cover positioned over the display and defining a front exterior surface, and a housing component coupled to the front cover and defining a chassis section below the front cover. The chassis section may define a first side facing the front cover, a second side opposite the first side and defining a battery mounting region, a first recess formed along the second side in the battery mounting region, and a second recess formed along the second side in the battery mounting region. The mobile phone may further include a battery coupled to the chassis section in the battery mounting region, a first adhesive positioned in the first recess and adhering the battery to the chassis section, and a second adhesive positioned in the second recess and adhering the battery to the chassis section.

A portable electronic device may include an enclosure defining an interior cavity and having a front cover, and a haptic engine positioned in the interior cavity. The haptic engine may include a first body component defining a first side of the haptic engine and including a first spring flexure and a first end element molded over a portion of the first spring flexure, a second body component defining a second side of the haptic engine opposite the first side and including a second spring flexure and a second end element molded over a portion of the second spring flexure, a movable mass component coupled to the first spring flexure and the second spring flexure, and a coil configured to induce a linear movement of the movable mass component in response to the actuation signal thereby producing a haptic output.

This application provides a film-like heat dissipation member, a bendable display apparatus, and a terminal device. The film-like heat dissipation member includes a heat dissipation layer. Composition and a structure of the heat dissipation layer are designed, so that a cutting-plane length of the heat dissipation layer changes in a surface bending process, can be bent repeatedly, and can implement uniform temperatures on two sides of the bendable display apparatus and the terminal device, thereby improving heat dissipation capabilities of the bendable display apparatus and the terminal device.

A thermal interface material (TIM) structure for directing heat in a three-dimensional space including a TIM sheet. The TIM sheet includes a lower portion along a lower plane; a first side portion along a first side plane; a first upper portion along an upper plane; a first fold between the lower portion and the first side portion positioning the first side portion substantially perpendicular to the lower portion; and a second fold between the first side portion and the first upper portion positioning the first upper portion substantially perpendicular to the first side portion and substantially parallel to the lower portion.

An electronic device having a display assembly is disclosed. Several layers may combine to form the display assembly. For example, the display assembly may include a touch sensitive layer (or touch detection layer), a display layer that present visual information, and a force sensitive layer (or force detection layer). The display layer may include a bend or curve that allows a portion of the display layer to bend around the force sensitive layer. Also, the connectors (that provide electrical and mechanical connections) may be positioned at different locations of the layers. For example, the display layer may include a connector on a first edge region, and the force sensitive layer may include a connector on a second edge region that is perpendicular, or at least substantially perpendicular, to the first edge region. By positioning the connectors on perpendicular edge regions, the display assembly may reduce its footprint.

The present invention relates to a method for enhancing boiling performance of chip surface comprising steps of mounting a heat pipe directly above the surface of the chip, and forming a porous structure for increasing the vaporization core on an upper surface of the heat pipe. Performing an enhancing treatment in boiling of the upper surface of the heat pipe by mounting the heat pipe directly above the chip makes a temperature field of the boiling surface uniform, increases the boiling area and vaporization core, strengthens the boiling heat transfer, and reduces the core temperature of the chip.

An electronic device having a display assembly is disclosed. Several layers may combine to form the display assembly. For example, the display assembly may include a touch sensitive layer (or touch detection layer), a display layer that present visual information, and a force sensitive layer (or force detection layer). The display layer may include a bend or curve that allows a portion of the display layer to bend around the force sensitive layer. Also, the connectors (that provide electrical and mechanical connections) may be positioned at different locations of the layers. For example, the display layer may include a connector on a first edge region, and the force sensitive layer may include a connector on a second edge region that is perpendicular, or at least substantially perpendicular, to the first edge region. By positioning the connectors on perpendicular edge regions, the display assembly may reduce its footprint.

This application provides a film-like heat dissipation member, a bendable display apparatus, and a terminal device. The film-like heat dissipation member includes a heat dissipation layer. Composition and a structure of the heat dissipation layer are designed, so that a tangent-plane length of the heat dissipation layer changes in a surface bending process, can be bent repeatedly, and can implement uniform temperatures on two sides of the bendable display apparatus and the terminal device, thereby improving heat dissipation capabilities of the bendable display apparatus and the terminal device.

A thermal interface material (TIM) structure for directing heat in a three-dimensional space including a TIM sheet. The TIM sheet includes a lower portion along a lower plane; a first side portion along a first side plane; a first upper portion along an upper plane; a first fold between the lower portion and the first side portion positioning the first side portion substantially perpendicular to the lower portion; and a second fold between the first side portion and the first upper portion positioning the first upper portion substantially perpendicular to the first side portion and substantially parallel to the lower portion.