An electronic device comprising a first portion and a second portion pivotably connected to each other is disclosed. The electronic device is pivotable between a closed position and an open position. The device comprises a magnetically attractable arrangement within or on the second portion and a magnetic arrangement comprising a magnet having a magnetic field and a magnetic shielding element disposed within or on the first portion. At least one of the magnet or the magnetic shielding element is configured to move translationally with respect to the other between a shielded position and an engaging position when the first portion is pivoted with respect to the second portion. In the shielded position, the magnetic shielding element at least partially reduces a portion of the magnetic field extending outside of the first portion. In the engaging position, the magnet engages the magnetically attractable arrangement.

An earphone case includes a body, a storage member, a cover, and a reset member. The body has a chamber and a fixing base. The base is securely disposed in the chamber. The storage member is disposed in the chamber, located above the fixing base, contacted with the body, and has multiple first magnetic parts. The cover is pivotally connected to the storage member and the fixing base, and the cover has multiple second magnetic parts. The reset member is disposed above the fixing base and connected to the body and the storage member respectively. In close mode, the cover completely covers the storage member. The multiple first magnetic parts and second magnetic parts are magnetically attracted to each other. In open mode, the cover is relatively separated from the storage member and rotated at an angle, such that the cover partially overlaps with the storage member.

The disclosure provides a display including a carrying main body, a flexible display panel, at least one magnet, and a plurality of electromagnets. The flexible display panel is disposed on the carrying main body and is adapted to unfold on the carrying main body. The at least one magnet is disposed on the flexible display panel. The electromagnets are disposed on the carrying main body. Magnetic poles of the electromagnets are adapted to change and drive the at least one magnet and the flexible display panel to move relatively to the carrying main body.

A device incorporating both a magnet and a living hinge may be employed to construct cases to protect electronic devices and to function as a closure for cases and lidded containers. Such cases often can be bent three 360 allowing the cases to be either closed protecting devices therein are closed upon themselves allowing the case to function to secure an electronic device to a substrate such as an article of clothing. The devices of the disclosure can also be used to organize and hold loose items together.

The present disclosure relates to fasteners for a variety of items including but not limited to luggage, clothing, handbags, etc. The fasteners have magnetic properties to ensure a solid yet removable connection between the fasteners. In at least one embodiment, a magnetic member is wrapped, at least partially, in a length of material thereby shielding the magnetic member from damage as well as assisting in coupling with another magnetic member.

A clamping mechanism comprising: a first part; a clamp coupled to said first part to enable the clamp to slide relative to said first part in a first linear direction, the clamp being provided with a first magnetic component; a second part for clamping by said clamp, the second part being provided with a second magnetic component. The mechanism is configured such that movement of the clamp in said first linear direction, between a clamping and an unclamped position, is effected by movement of the first part and the clamp, relative to said second part, in a second linear direction substantially orthogonal to said first linear direction as a result of alignment and misalignment of the magnetic components.

The present disclosure relates to a magnetic assembly structure which utilizes a magnetic attraction or repulsion effect generated by two magnetic components to make two buckle structures automatically engaged to each other. The magnetic assembly structure of the present disclosure has a first main body and a second main body, and via the hardware design of disposing magnetic components and buckle structures respectively on the first main body and the second main body, the first and second main bodies rotate in respect to each other due to the magnetic attraction or repulsion effect, so as to efficiently engage the two buckle structures each other. Thus, it actually eases the installation and uninstallation of the appliance to which the magnetic assembly structure is applied, and the costs of installation and consuming time are reduced.

In accordance with aspects of the present disclosure, an apparatus includes a holder having a flexible sheet with a foldable portion that is foldable along an axis to form an upper portion and a lower portion of the flexible sheet, wherein the upper portion contains at least one magnet embedded therein and the lower portion contains at least one magnet embedded therein. The apparatus further includes at least one rigid container dimensioned to fit within the holder when the holder is folded, where the rigid container includes at least a first magnet with the first magnet located to engage the at least one magnet embedded in the lower portion of the holder and the at least one magnet embedded in the upper portion of the holder.

A magnetic assembly structure has a main body and an inserting component. A first receiving slot of the main body receives a first magnetic component, and a second receiving slot of the main body penetrates a main body surface to form a main body opening on the main body surface. An engagement slot of the main body is disposed between the first receiving slot and the second receiving slot, communicated with the second receiving slot, and has a contacting surface being away from the main body surface with a distance. The receiving slot of the inserting component receives a second magnetic component. The inserting component is inserted into the second receiving slot via the main body opening, and the second magnetic component moves into the engagement slot. The magnetic assembly is assembled with a less force, has higher safety, and is hard to be disassembled without allowance or explanations.