A carrier tape, cover tape or static shielding bag for transportation of electronic components is constructed of polymers and carbon nanotubes being between 0.01% and 3% by weight. The carbon nanotubes may have any number of walls and any desired size of diameter dimension which is less than approximately 100 nm. The carrier tape, cover tape or bags including the carbon nanotubes have a static dissipative range measured between 110.sup.5 and 110.sup.12 /sq and a light transmittance value of between 60% and 90%. The carrier tape, cover tape or bags including the carbon nanotubes reduce surface defects, high density entanglements and agglomerations. The static shielding bags including the carbon nanotubes may be formed as sheets which are manufactured into a desired size of bag.

A device used in manufacturing for transportation of workpieces of different sizes includes a supporting part, the supporting part including a support plate and parallel and detachable separator plates mounted to the support plate. The support plate includes bottom, first side plate, second side plate, and connecting plate. First and second side plates are parallel and opposing, the connecting plate is connected therebetween. Each separator plate includes a main portion and a protruding first limiting portion. The first limiting portion of one separator plate abuts against the first side plate, and each first limiting portion of other separator plates abuts against the main portion of a neighboring separator plate. The gaps formed between the main portions of neighboring separator plates carry the workpieces being transported.

The lid body which includes a lid body main body having a lid body inner face and a lid body outer face, is detachable to the opening rim portion, and can close the container main body opening portion, wherein the lid body inner face forms the substrate storing space together with the main body inner face when the container main body opening portion is closed. The external component made from resin that is mounted to at least one of a part of the container main body other than the main body inner face, and a part of the lid body main body other than the lid body inner face. The external component is annealed.

According to an embodiment, a magnetic shield tray includes a main body with a plate form including a magnetic material, and mount portions as holes disposed in the main body. The magnetic material is exposed on an inner surface of the holes.

A packing container for accommodating a display panel is described. The packing container includes a packing main body having a receiving recess, which includes a first receiving zone and a second receiving zone, and a limiting element disposed on the second receiving zone, wherein the limiting element and the sidewall of the second receiving zone form a limiting accommodating space to constrain and accommodate a circuit board of the display panel.

A carrier tape, cover tape or static shielding bag for transportation of electronic components is constructed of polymers and carbon nanotubes being between 0.01% and 3% by weight. The carbon nanotubes may have any number of walls and any desired size of diameter dimension which is less than approximately 100 nm. The carrier tape, cover tape or bags including the carbon nanotubes have a static dissipative range measured between 110.sup.5 and 110.sup.12 /sq and a light transmittance value of between 60% and 90%. The carrier tape, cover tape or bags including the carbon nanotubes reduce surface defects, high density entanglements and agglomerations. The static shielding bags including the carbon nanotubes may be formed as sheets which are manufactured into a desired size of bag.

Equipment transport bag assemblies (20, 92, 98, 145, 152, 182) each including an upright, open-top, equipment-receiving bag (22, 110, 158) with associated equipment-handling assemblies (24, 92, 102, 164, 184). The assemblies (24, 92, 102, 164, 184) have load-bearing strap units (34, 114, 166, 186) operably associated with the transport bags (22, 110, 158) so that the strap units (34, 114, 166, 186) bear the primary loads during lifting and handling of the bag assemblies (20, 92, 98, 145, 152, 182).

A packaging device packages a display device. The packaging device includes frames sequentially connected end to end and arranged into a ring, the frames are made of a material having supporting strength, the frames are respectively provided with accommodation recesses therein, the packaging device further comprises an elastic cushion attached to an inner wall of the accommodation recess, and edges of the display device respectively fasten the accommodation recesses and touch the cushion. The packaging device reduces the packaging volume of the display device and prevents the packaged display device from being deformed or breaking into fragments.

A battery packaging material including a laminate that is provided with a barrier layer, a heat-fusible resin layer positioned on one surface side of the barrier layer, and a polyester film positioned on the other surface side of the barrier layer. When the infrared absorption spectrum on the surface of the polyester film in 18 directions at intervals of 10 from 0 to 180 is obtained using the total reflection method of Fourier transform infrared spectroscopy, the ratio (surface orientation degree, Y.sub.max/Y.sub.min) of the maximum value Y.sub.max and the minimum value Y.sub.min of the ratio (Y.sub.1340/Y.sub.1410) of the absorption peak intensity Y.sub.1340 in 1340 cm.sup.1 and the absorption peak intensity Y.sub.1410 in 1410 cm.sup.1 in the infrared absorption spectrum is in the range of 1.4-2.7.

An object to be achieved by the present invention is to provide a gas barrier film having excellent acid resistance, transparency, and gas barrier properties. The gas barrier laminated body of the present invention is a laminate, in which an inorganic thin-film layer is laminated onto at least one of surfaces of a polymer substrate, and the inorganic thin-film layer mainly contains Al and Si, and a ratio of an Al content amount between before and after treatment of immersing the laminate into aqueous solution of hydrochloric acid that has concentration of 1 mol/L for one hour satisfies a formula of (Al Content Amount After Treatment)/(Al Content Amount Before Treatment)?100?75.