To provide a pouch that allows a displacement of the formation position of a film through portion to be detected. A pouch includes an inner film (70) disposed in a pouch body (20), the inner film (70) including a first fixing portion (71) fixed to a pouch body (20), a second fixing portion (72) fixed to the pouch body (20), an inner placement portion (75) that is disposed in the pouch body (20) without being fixed to the pouch body (20), and a plurality of film through portions (76) penetrating in a film thickness direction, the plurality of film through portions (76) including a first film-through portion (76a) at least partially formed on the first fixing portion (71) and an inner film-through portion (76c) formed on the inner placement portion (75), the first film-through portion (76a) being overlapped on the body film in a bag-making sealing portion (23).

[Object] To provide a building material, a stacked body of building materials, and a building-material construction method capable of improving the construction properties while suppressing a design surface from being damaged. [Solution] A building material includes a substantially rectangular plate-shaped building material body 2 that includes a first face 2F and a design surface 3 within the first face 2F; and a protective sheet S1 that is affixed to the building material body 2 in a peelable manner. The design surface 3 includes a covered region C1 that is covered with the protective sheet S1 and thereby protected and an exposed region B1 that is not covered with the protective sheet S1 and that extends along a first design end portion 3D, which is an end portion of the design surface 3.

Provided is a method comprises: continuously forming an elongated, glass film having marginal portions from molten glass into a given shape having two marginal portions, in width-directional opposite edge regions thereof, wherein the glass film having marginal portions has the marginal portions, and an effective portion formed in a width-directional central region of the glass film having marginal portions; annealing the glass film having marginal portions; continuously forming resin tapes on the glass film having marginal portions at positions adjacent to and away by a given distance from the respective marginal portions, to extend in a length direction of the glass film having marginal portions; and continuously removing each of the marginal portions from the glass film having marginal portions, along a position between the marginal portion and a corresponding one of the resin tapes, or at a given width-directional position within the corresponding resin tape.

A battery cast-on-strap machine unloading apparatus includes a first and a second unit. Each unit includes a rotary drive mechanism; and, a pinion co-axial with and directly driveable by the rotary drive mechanism. The apparatus further includes an elongate rack. The rack includes teeth along a first side and an opposing second side. The first and second units are mounted adjacent to each other on the rack. Operation of each drive mechanism causes rotation of the respective pinion to be converted into linear motion of the respective unit along the rack. Adjacent rotary drive mechanisms are located on opposing sides of the rack, such that the pinion of the first unit meshes with the teeth along the first side of the rack, and the pinion of the adjacent second unit meshes with the teeth along the opposing second side of the rack.

Provided are a building board package suitable to suppress generation of a gloss that could be caused as a result of pressing a coating film on the surface of a building board, and a method for manufacturing the building board package. A building board package X1 according to the present invention includes a first building board 10, and a packing sheet 20 stacked on top of the first building board 10. The first building board 10 has a first surface 11 on the packing sheet 20 side, and a second surface 12 opposite the first surface 11. The first surface 11 includes a first coating film surface 11A. The packing sheet 20 has a third surface 21 on the first building board 10 side, and a fourth surface 22 opposite the third surface 21. The third surface 21 is in contact with the first coating film surface 11A. An absolute value of a difference between a 60-degree gloss value of the first coating film surface 11A and a 60-degree gloss value of the third surface 21 is 3.0 or less, and an absolute value of a difference between an 85-degree gloss value of the first coating film surface 11A and an 85-degree gloss value of the third surface 21 is 3.0 or less. A method for manufacturing a building board package according to the present invention includes the step of stacking the first building board 10 and the packing sheet 20 on top of each other such that the first coating film surface 11A and the third surface 21 are in contact with each other.

A unit for transporting eggs includes a platform carrying superimposed horizontal layers of egg-holder trays and intermediate partitions interposed between the plurality of superimposed horizontal layers. Parallel to two opposite sides of the partition are stop elements projecting upwards suitable to cooperate with corresponding lower abutments of the egg-holder trays of the lowest layer of the corresponding plurality of superimposed horizontal layers. The stop elements are spaced by the two opposite sides of the partition, towards the inside thereof.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.