The invention relates to a melting fuse, especially for a motor vehicle that has a high-voltage circuit, comprising an electrically insulating housing inside of which there is a fusible conductor that connects two contacts with each other, whereby, between two longitudinal areas that are adjacent to each other, the fusible conductor has a rotation point around which the longitudinal areas can be rotated in case of a thermo-mechanical expansion.

A fuse component (1) has a fuse element (2). The fuse element (2) is located inside an isolating body (3) and the fuse element (2) extends between the two end faces of the isolating body (3). Each of the end faces of the isolating body (3) are closed by electrical conductive end caps (4) and the end caps (4) are in electrical contact with the fuse element (2). The isolating body (3) includes at least two shells (5a, 5b); at least in the region of the end caps (4), and the shells (5a, 5b) in the assembled state form a channel (6) to receive the fuse element (2).

A fuse component (1) has a fuse element (2). The fuse element (2) is located inside an isolating body (3) and the fuse element (2) extends between the two end faces of the isolating body (3). Each of the end faces of the isolating body (3) are closed by electrical conductive end caps (4) and the end caps (4) are in electrical contact with the fuse element (2). The isolating body (3) includes at least two shells (5a, 5b); at least in the region of the end caps (4), and the shells (5a, 5b) in the assembled state form a channel (6) to receive the fuse element (2).

Various embodiments include a fuse electrically connecting two connection regions comprising: a heat sink; a set of layers arranged on a surface of the heat sink, the set of layers including an electrically insulating layer arranged on the heat sink and an electrically conductive conductor layer arranged on a side of the insulation layer facing away from the heat sink; and an electrical connecting path between the connection regions. The surface of the heat sink defines two material cutouts. A portion of the heat sink arranged between the material cutouts forms a bridge element. The set of layers is disposed on the bridge element.

Various embodiments include a fuse electrically connecting two connection regions comprising: a heat sink; a set of layers arranged on a surface of the heat sink, the set of layers including an electrically insulating layer arranged on the heat sink and an electrically conductive conductor layer arranged on a side of the insulation layer facing away from the heat sink; and an electrical connecting path between the connection regions. The surface of the heat sink defines two material cutouts. A portion of the heat sink arranged between the material cutouts forms a bridge element. The set of layers is disposed on the bridge element.

A fuse including a first housing part and a second housing part that are joined together to define a cavity, a fuse element disposed within the cavity, a first terminal extending from a first end of the fuse element and out of the housing, and a second terminal extending from a second end of the fuse element and out of the housing, the housing having a vent channel extending from an outer surface of the housing to the cavity for allowing vapor to escape from the cavity.

Disclosed is a protective element, comprising an insulator, a fusible element, and electrodes, wherein the insulator covers a meltable part of the fusible element. The electrodes are disposed at two ends of the insulator. Two ends of the fusible element are electrically connected to the electrodes. Wave absorbing structures are disposed around the fusible element in the insulator, a plurality of protrusions is provided on the wave absorbing structures, and the protrusions face the fusible element. Distances exist between the wave absorbing structures and the fusible element. The present invention improves the shape of a fusible element and designs wave absorbing structures which can resist an impact, energy waveforms can be destroyed, impact energy is dispersed to the periphery so as to achieve the aim of wave (energy) absorbing, a breaking performance of a protective element can be at least doubled by virtue of the design of the wave absorbing structure, a manufacturing process is simple, and the protective element is suitable for batch production.

Disclosed is a protective element, comprising an insulator, a fusible element, and electrodes, wherein the insulator covers a meltable part of the fusible element. The electrodes are disposed at two ends of the insulator. Two ends of the fusible element are electrically connected to the electrodes. Wave absorbing structures are disposed around the fusible element in the insulator, a plurality of protrusions is provided on the wave absorbing structures, and the protrusions face the fusible element. Distances exist between the wave absorbing structures and the fusible element. The present invention improves the shape of a fusible element and designs wave absorbing structures which can resist an impact, energy waveforms can be destroyed, impact energy is dispersed to the periphery so as to achieve the aim of wave (energy) absorbing, a breaking performance of a protective element can be at least doubled by virtue of the design of the wave absorbing structure, a manufacturing process is simple, and the protective element is suitable for batch production.

A dual element electrical fuse includes at least one high overcurrent fusible element and a low overcurrent fusible element connected to one another inside a housing. The low overcurrent fusible element includes a single sided circuit board and a releasable conductive element that more simply provides low overcurrent protection and manufacturing efficiency with improved quality.

A dual element electrical fuse includes at least one high overcurrent fusible element and a low overcurrent fusible element connected to one another inside a housing. The low overcurrent fusible element includes a single sided circuit board and a releasable conductive element that more simply provides low overcurrent protection and manufacturing efficiency with improved quality.