An electronic component conveying tape includes an elongated carrier tape including recessed storage portions at regular intervals in a length direction, and each storing an electronic component, and an elongated cover tape attached to one surface in a thickness direction of the carrier tape to cover openings of the storage portions. The carrier tape is made of paper, and fibers included in the carrier tape are sloped toward the thickness direction relative to the length direction.

An electronic component conveying tape includes an elongated carrier tape including recessed storage portions at regular intervals in a length direction, and each storing an electronic component, and an elongated cover tape attached to one surface in a thickness direction of the carrier tape to cover openings of the storage portions. The carrier tape is made of paper, and fibers included in the carrier tape are sloped toward the thickness direction relative to the length direction.

A cover film having at least a substrate layer and a sealant resin layer, wherein the sealant resin layer is formed to contact one surface of the substrate layer or is formed on an intermediate resin layer contacting one surface of the substrate layer, and the sealant resin layer contacting the substrate layer or the intermediate resin layer contacting the substrate layer contains an epoxidized fatty acid or a derivative thereof. The epoxidized fatty acid or a derivative thereof in the sealant resin layer contacting the substrate layer or in the intermediate resin layer contacting the substrate layer is preferably at a content of 0.5 parts by mass or less with respect to 100 parts by mass of a resin component constituting the intermediate resin layer contacting the substrate layer and/or the sealant resin layer contacting the substrate layer.

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 1×10.sup.5 and 1×10.sup.12 Ω/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 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 1×10.sup.5 and 1×10.sup.12 Ω/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.

An integral injection molded strip (10) of a single plastic material is provided, the strip comprising a plurality of vials (20) connected by frangible (breakable) connecting members (38). Each vial (as molded as part of the integral injection molded strip) has a neck portion (30) with an internal delivery passage (31) and a squeezable body portion (22), the squeezable body portion having an internal chamber (23) for holding a single dose of a fluid product (50), the chamber (23) having an open top end (24) fluidly connected to the internal delivery passage (31) in the neck portion, and the chamber having a bottom end (25) adapted for filling with the fluid product. The internal delivery passage (31) (of the neck portion) has an open bottom end (33) fluidly connecting to the body chamber, an opposing open top end (32), and an integral injection molded internal membrane (34) (formed in the delivery channel during injection molding of the integral strip of vials) that seals the delivery passage (31) prior to being pierced by a needle (62) of a dispensing device (60).

An integral injection molded strip (10) of a single plastic material is provided, the strip comprising a plurality of vials (20) connected by frangible (breakable) connecting members (38). Each vial (as molded as part of the integral injection molded strip) has a neck portion (30) with an internal delivery passage (31) and a squeezable body portion (22), the squeezable body portion having an internal chamber (23) for holding a single dose of a fluid product (50), the chamber (23) having an open top end (24) fluidly connected to the internal delivery passage (31) in the neck portion, and the chamber having a bottom end (25) adapted for filling with the fluid product. The internal delivery passage (31) (of the neck portion) has an open bottom end (33) fluidly connecting to the body chamber, an opposing open top end (32), and an integral injection molded internal membrane (34) (formed in the delivery channel during injection molding of the integral strip of vials) that seals the delivery passage (31) prior to being pierced by a needle (62) of a dispensing device (60).

A sampling device having a lower portion with a sample container. A cap is moveably attached with the lower portion and includes a cutting edge configured for cutting a leaf. When the cap is attached to the lower portion with a leaf there between, a leaf sample is deposited into the sample container of the lower portion. The cap includes a vent in fluid communication with the sample container such that the leaf sample is dried. A detachable label can extend from the lower portion.

A sampling device having a lower portion with a sample container. A cap is moveably attached with the lower portion and includes a cutting edge configured for cutting a leaf. When the cap is attached to the lower portion with a leaf there between, a leaf sample is deposited into the sample container of the lower portion. The cap includes a vent in fluid communication with the sample container such that the leaf sample is dried. A detachable label can extend from the lower portion.

In an embodiment a storage device includes a base carrier extending along a main surface having a surface structuring, a carrier foil including a first main surface and a second main surface, wherein the first main surface is fixable to or arrangeable on the main surface of the base carrier, and wherein the components are fixable to the second main surface and a fixing frame fixing the carrier foil, which is fixed or positioned to the main surface of the base carrier, to the base carrier and acting as a releasable clamp so that the carrier foil is clampable and securable in or to the base carrier.