Abstract:
A chip resistor having first and second opposite ends includes a rigid insulated substrate having a top surface and an opposite bottom surface, a first electrically conductive termination pad and a second electrically conductive termination pad, both termination pads on the top surface of the rigid insulated substrate, a layer of resistive material between the first and second electrically conductive termination pads, and a first and a second flexible lead, each made of an electrically conductive metal with a solder enhancing coating. The first flexible lead attached and electrically connected to the first electrically conductive termination pad and the second flexible lead attached and electrically connected to the second electrically conductive termination pad. Each of the flexible leads has a plurality of lead sections facilitating bending around the end of the chip resistor.
Abstract:
Provides are a light emitting apparatus and a light unit having the same. The light emitting apparatus comprises a light emitting device comprising a light emitting element and a plurality of external leads, and a plurality of electrode pads under the light emitting device.
Abstract:
A chip fuse includes a substrate, a fuse element extending on the substrate, and first and second wire leads coupled to the fuse element. Contact pads may extend over portions of the fuse element and establish electrical connection to the first and second leads. A conductive medium such as solder encircles the substrate to securely form a mechanical and electrical connection to the leads.
Abstract:
An electronic component has an element, a pair of terminal portions which are disposed on the element, and an external covering material which covers a part of the terminal portions and the element. The electronic component is configured such that inclined portions are disposed on corner portions of a bottom surface and side surfaces of the external covering material, and the terminal portions are protruded from corner portions where the inclined portions and the bottom surface of the external covering material intersect.
Abstract:
A staggered light unit has a top-bottom electrode lead. The light unit is insertable into a substrate having a metal/insulation/metal sandwich structure.
Abstract:
The present invention is to provide a printed wiring board which can certainly prevent damage of conductive pattern caused by the terminal. The printed wiring board has a board, a conductive pattern, a through-hole and a non-conductive area. A lead wire of resistance mounted on the printed wiring board is inserted into the through-hole 4. The lead wire projects from a surface of the board, and is bent close to the surface. The non-conductive area is formed into a fan-shaped shape enlarging toward a tip of the lead wire from a center of the through-hole. Since the bent lead wire is arranged on the non-conductive area, the non-conductive area can prevent damage of the conductive pattern which is caused by touching the lead wire to the conductive pattern.
Abstract:
An electric power supply platform (1) made up of an upper conductive layer (2), a lower conductive layer (3), and a non-conductive insulating layer (4) sandwiched between the conductive layers (2), (3). Specially designed light emitting diodes (LEDs) (9) and a variety of other electronic components, each having one short lead (11) and one upper insulated long lead (10), may be removably attached to, displayed, and powered by the power platform (1) simply by inserting leads into the display surface (5) of the power platform (1). The leads of the LEDs (9) and other electronic components are different lengths so that the short lead (11) only comes into contact with the upper conductive layer (2) and the long lead (10) only comes into contact with the lower conductive layer (3) ensuring proper polarity. The leads (10), (11) of the LEDs (9) and/or other electronic components may be inserted into the display surface (5) at any location allowing the user to make any design he/she desires.
Abstract:
A surface light emitting diode module includes a conductive substrate including a first electrode section. A first hole is formed on the first electrode section. The surface light emitting diode module further includes a surface light emitting diode installed on the conductive substrate. The surface light emitting diode includes a first electrode pin for contacting with the first electrode section. A second hole is formed on the first electrode pin and disposed in a position corresponding to the first hole. The surface light emitting diode module further includes a first fixing component passing through the second hole and the first hole so as to fix the conductive substrate and the surface light emitting diode.
Abstract:
A vehicular lamp includes a lamp body; a plurality of LED light sources disposed inside a lamp chamber formed by a front cover positioned in front of the lamp body; and a lighting circuit portion positioned behind the LED light sources. The LED light source is electrically connected to a conductive bus bar, and forms a light-emitting surface at a position opposite the front cover. The lighting circuit portion is formed on the back side of the light-emitting surface of the LED light source with respect to the front cover, and a circuit element thereof is electrically connected to the conductive bus bar. The conductive bus bar to which the LED light source is connected and the conductive bus bar to which the circuit element is connected are conductively connected.
Abstract:
A sensor unit (1) has a metal plate (10), a resin molded portion (20) and an oil temperature sensor (2). Busbars (4) made of a metal are arranged in the resin molded portion (20). Since the busbars (4) are insert-molded while having the exposed ends (4A) thereof tightly held by a pair of forming dies, a distance between the exposed ends (4A) and the placing surface 10A is held constant. Further, gate marks (5D) of the oil temperature sensor (2) are accommodated in recesses (10B) of the placing surface (10) and engaging grooves (9) and engaging projections (26A) are engaged. Thus, the oil temperature sensor (2) can be held in a proper posture. Additionally, the oil temperature sensor (2) can be held on the placing surface (10A) by riveting the exposed end (4A) and a terminal (8) of the oil temperature sensor (2).