A reticle pod with antistatic capability includes a base and plural of support members. The base has a carrying surface having a recess formed thereon and defined by a bottom surface. The support members encircle the carrying surface of the base and are adapted to support a reticle. The recess is defined by a depth extending between the carrying surface and the bottom surface. The depth ranges from 300 μm to 3400 μm to thereby weaken the electrostatic force exerted upon particles on the carrying surface.

The invention discloses a reticle pod for receiving a reticle. The reticle pod includes a base and plural support device provided on the base for supporting the reticle. A first distance is defined between a peripheral area of a bottom surface of the reticle and an upward facing top surface of the base. A second distance is defined between a central area of the bottom surface of the base and the upward facing top surface of the base, wherein the central area is encircled by the peripheral area. The second distance is larger than the first distance.

The invention discloses a substrate storage apparatus having a detecting device detachably connecting to an outer pod. The detecting device includes a sensing member having a sensing terminal, a cavity and a sensor. The sensing terminal detachably connects to the outer pod such that the sensing terminal exposes in an accommodating space inside of the outer pod. The cavity receiving the sensor extends to an outside of the outer pod and the accommodating space. The cavity communicates with the accommodating space through the sensing terminal, allowing the sensor to read information regarding the accommodating space.

The present disclosure relates to a control module having a connector and a housing. The housing defining a first opening that receives the connector, and a hermetically sealed interior housing at least one electronic component. The electronic component is electrically coupled to the connector. The control module further includes a retaining clip in physical contact with the housing and mechanically coupling the at least one electronic component to the connector.

A mounting structure for mounting an electrolytic capacitor on a printed circuit board (PCB) of an airbag electronic control unit (ECU) includes a cap for receiving a lead end of the capacitor. The cap includes openings for receiving electrical leads of the capacitor. The cap supports electrical connectors, which electrically contact the electrical leads when a lead end of the capacitor is installed in the cap. The electrical connectors include portions for interfacing with the PCB to electrically connect the electrical connectors to the PCB. The cap also includes a vent that provides fluid communication from inside the cap to outside the cap. The vent is configured to vent dielectric liquids and gases discharged from the lead end of the capacitor during thermal cycles and/or charging cycles of the capacitor.

A control unit which meets desired packaging requirements, eliminates the need for right-angle or L-shaped pins, and has a reduced footprint. The control unit includes a connector, a circuit board connected to the connector, and an encapsulation housing. The encapsulation housing surrounds at least a portion of the circuit board and at least a portion of the connector. The connector includes a base flange, a shroud integrally formed with the base flange, a plurality of pins extending through the base flange and partially extending into the circuit board. The connector also includes at least one grounding pin connected to the base flange which partially extends into the circuit board. A bushing extends through a mounting post formed as part of the base flange such that the bushing is in contact with the grounding pin, where the grounding pin and the bushing are part of a grounding connection.

A connector device that includes a circuit board; a connector attached to the circuit board; a plurality of collars for external attachment; a first molded resin that is made of a first resin material whose melting point or softening point is 230° C. or less, and covers the entire circuit board and part of the connector; and a second molded resin that is welded to the first molded resin, is made of a second resin material whose melting point or softening point is higher than that of the first resin material for the first molded resin, and covers outer circumferences of the collars.

A shock resistant fuselage system includes first and second fuselage side walls, each of the first and second fuselage side walls having a plurality of guide posts, and a printed circuit board (PCB) rigidly attached to at least one of the first and second fuselage side walls, the PCB having a plurality of guide slots, each of the plurality of guide posts slideably seated in a respective one of the plurality of guide slots so that elastic deformation of the PCB is guided by the guide slots between the first and second fuselage side walls.

The present disclosure relates to a power module comprising a substrate, first and second pluralities of vertical power devices, and first and second terminal assemblies. The substrate has a top surface with a first trace and a second trace. The first plurality of vertical power devices and a second plurality of vertical power devices are electrically coupled to form part of a power circuit. The first plurality of vertical power devices are electrically and mechanically directly coupled between the first trace and a bottom of a first elongated bar of the first terminal assembly. The second plurality of vertical power devices are electrically and mechanically directly coupled between the second trace and a bottom of a second elongated bar of the second terminal assembly.

An electrical assembly includes a printed circuit board substrate, at least one electrical component which is arranged on the printed circuit board substrate and with which the printed circuit board substrate makes electrical contact, a protective cap which is arranged above the electrical component, and a sheathing material which is applied to the printed circuit board substrate over the protective cap and which covers at least the protective cap on the outside in such a way that the protective cap is provided with at least one filling opening. The sheathing material is introduced through the at least one filling opening into a cap interior between the protective cap and the printed circuit board substrate in such a way that a clearance, which is not filled with the sheathing material and which directly adjoins the at least one electrical component, remains between the protective cap and the printed circuit board substrate.