In various embodiments, an arrangement is provided. The arrangement may include a plurality of chips; a chip carrier carrying the plurality of chips, the chip carrier including a chip carrier notch; and encapsulation material encapsulating the chip carrier and filling the chip carrier notch; wherein the outer circumference of the encapsulation material is free from a recess.

In various embodiments, an arrangement is provided. The arrangement may include a plurality of chips; a chip carrier carrying the plurality of chips, the chip carrier including a chip carrier notch; and encapsulation material encapsulating the chip carrier and filling the chip carrier notch; wherein the outer circumference of the encapsulation material is free from a recess.

A chip accommodation tray for accommodating a plurality of chips includes a holding sheet for holding the chips on a face side thereof, the holding sheet having a tack force and a plurality of first pores formed therethrough, and a frame including a bottom wall supporting a reverse side of the holding sheet, the bottom wall having a plurality of second pores formed therethrough, and side walls erected from the bottom wall in surrounding relation to the holding sheet. Air is supplied from below the bottom wall of the frame through the second pores and the first pores and ejected toward lower surfaces of the chips held on the holding sheet, thereby peeling the chips off the holding sheet.

Introduced here are carrier assemblies that include a rigid tray having a deck area with a patterned surface of cavities for receiving semiconductor components. The cavities can be designed to accommodate semiconductor components of different form factors (e.g., having different shapes, sizes, etc.). Moreover, an adhesive film can be affixed to the deck area to ensure that the semiconductor components are securely held against the top surface of the rigid tray. In some instances the adhesive film substantially conforms to the deck area, while in other instances the adhesive film extends across the opening of each cavity located in the deck area. Semiconductor component(s) can be secured to the carrier assembly based on the adhesiveness provided by the adhesive film, mechanical force provided the cavities, electrostatic force provided by the cavities, or any combination thereof.

Disclosed are a multilayer styrenic resin sheet including 10 to 50 laminated layers which are each made of a styrenic resin composition that includes 29 to 65 mass % of a styrene/conjugated diene copolymer (A), 51 to 15 mass % of a polystyrene resin (B) and 20 to 9 mass % of an impact-resistant polystyrene resin (C) and which each have an average thickness of 2 to 50 m; and a packaging material (such as carrier tape or tray) for electronic components which is formed from the multilayer styrenic resin sheet. The melt tension of the styrenic resin composition at 220 C. is preferably 10 to 30 mN, and the content of the conjugated diene is preferably 10 to 25 mass % relative to 100 mass % of the copolymer (A).

Methods, systems and devices for protecting partially processed electronic parts, are disclosed. In some embodiments, a method for protecting electronic parts includes applying a first protective sheet on one or more partially-processed semiconductor devices, removing the first protective sheet, and performing a semiconductor-processing operation on the one or more partially-processed semiconductor devices. In some embodiments, a semiconductor processing system for protecting electronic parts includes one or more partially-processed semiconductor devices, and a first protective sheet applied on the one or more partially-processed semiconductor devices, the first protective sheet being subsequently removed, and a semiconductor-processing operation being performed on the one or more partially-processed semiconductor devices.

Implementations of a package tray may include a base and a grid of electromagnetic radiation reflectors coupled to a largest planar side of the base; wherein sidewalls of the grid of electromagnetic radiation reflectors may be configured to direct electromagnetic radiation toward sides of a plurality of semiconductor packages located within the grid. The electromagnetic radiation may be configured to assist in curing a component of the plurality of semiconductor packages.

The invention relates to a device for at least partially drying separated electronic components comprising: a carrier for the electronic components; a moisture-absorbing material; and a holder covered with the moisture-absorbing material, wherein the holder and the carrier are displaceable relative to each other such that the electronic components for drying can be brought into contact with the moisture-absorbing material.

The invented method is to realize a silicon chip carrier using wet bulk micromachining of silicon. In the silicon chip carrier, three (or more) supports are realized solely based on the wet etching of the silicon. The fabricated supports are triangular in shape and provide a minimum contact area between the sensing element and carrier. The invention provides a simple, cost-effective fabrication technology, which uses anisotropic wet etchant for silicon bulk-micromachining. A fabricated silicon wafer can be diced as per the requirement of single/multiple channel IR detectors. These chip carriers will cut down the IR detector cost with attractive lower thermal conductance in the field of gas sensors, spectrometry, thermal imaging, and fire detection.

The embodiments of the present application provide a carrier plate and a transferring device. The carrier plate particularly includes a transporting base plate, a dissociation regulating feature and a dissociable-adhesive layer that are sequentially arranged, the dissociation regulating feature is configured to regulate a dissociation accuracy of the dissociable-adhesive layer, and the dissociable-adhesive layer is configured to be connected to a plurality of light-emitting-diode chips. The carrier plate can increase the yield and the dissociation accuracy of the light-emitting-diode chips, which can increase the yield in the process of the mass transfer and the efficiency of the mass transfer of the light-emitting-diode chips.