The present invention relates to a method for providing a product viewing window in a container. The container has at least a body ply and a liner ply, wherein the body ply has at least one aperture therethrough. The liner ply is adhered to the inner surface of the body ply and has a portion extending across the aperture, forming a window into the container. The method involves providing a window-finishing machine that comprises at least two platens and, optionally, a machine pocket positioned between them, a heating element extending through at least one of the platens, and a pressurized air device that is adapted to release pressurized air into the container through at least one of the platens. The container is engaged between the platens in an airtight manner and, optionally, the container window is positioned adjacent the inside wall of the machine pocket. The heating element heats the window of the container to the desired temperature, pressurized air is injected into the container such that the window is forced at least partially through the aperture of the container (and optionally into contact with the machine pocket wall), and the container window is then cooled to the desired temperature.

There is provided an ejection material receiving unit capable of increasing the filling amount of ejection material with as little enlargement of the container itself as possible and an ejection material ejecting apparatus including the unit. Therefore, an ejection material receiving unit includes: a first receiving space capable of receiving ejection material; a second receiving space capable of receiving liquid; and a flexible member separating the first receiving space and the second receiving space, and is characterized in that the flexible member has a concave part which takes a concave shape in a state where the first receiving space is not filled with the ejection material and the second receiving space is not filled with the liquid, and the concave shape is a shape dented toward the second receiving space from the first receiving space, and is also a shape conforming to a wall forming the second receiving space.

There is provided an ejection material receiving unit capable of increasing the filling amount of ejection material with as little enlargement of the container itself as possible and an ejection material ejecting apparatus including the unit. Therefore, an ejection material receiving unit includes: a first receiving space capable of receiving ejection material; a second receiving space capable of receiving liquid; and a flexible member separating the first receiving space and the second receiving space, and is characterized in that the flexible member has a concave part which takes a concave shape in a state where the first receiving space is not filled with the ejection material and the second receiving space is not filled with the liquid, and the concave shape is a shape dented toward the second receiving space from the first receiving space, and is also a shape conforming to a wall forming the second receiving space.

An article of footwear includes a sole having a lower surface, and a reactive element disposed on the lower surface of the sole. The reactive element has an exposed surface, and the reactive element is configured to transition the exposed surface between a first state and a second state in response to a compression force applied to the reactive element by an external ground surface in a user activity, to prevent accumulation of ground surface material, such as mud, dirt, clay, sand, slush, etc., compacting on the sole of the article of footwear in the user activity. The reactive element may include an elastomeric dome shaped popper that compresses flat in response to a compression force and then pops back to a non-compressed state in response to release of the compression force.

An article of footwear includes a sole having a lower surface, and a reactive element disposed on the lower surface of the sole. The reactive element has an exposed surface, and the reactive element is configured to transition the exposed surface between a first state and a second state in response to a compression force applied to the reactive element by an external ground surface in a user activity, to prevent accumulation of ground surface material, such as mud, dirt, clay, sand, slush, etc., compacting on the sole of the article of footwear in the user activity. The reactive element may include an elastomeric dome shaped popper that compresses flat in response to a compression force and then pops back to a non-compressed state in response to release of the compression force.

The method of the present invention for producing a shaped film includes a step of arranging a thermoplastic resin film to divide a space into a first space located on one surface side of the film, and a second space located on the other surface side, a step of heating the thermoplastic resin film, a step of curving the thermoplastic resin film in one space by using a difference in pressure between the first space and the second space, a step of stopping the curving step of the thermoplastic resin film in a state where at least a convex curved surface of both surfaces of the film is exposed into the space, and a step of cooling the curved film.

The method of the present invention for producing a shaped film includes a step of arranging a thermoplastic resin film to divide a space into a first space located on one surface side of the film, and a second space located on the other surface side, a step of heating the thermoplastic resin film, a step of curving the thermoplastic resin film in one space by using a difference in pressure between the first space and the second space, a step of stopping the curving step of the thermoplastic resin film in a state where at least a convex curved surface of both surfaces of the film is exposed into the space, and a step of cooling the curved film.

In a method for producing a pipe made of a fiber-reinforced thermoplastic material, two workpieces of the material are provided. The workpieces are introduced into a tool having a core and two part molds surrounding the core. The workpieces are heated and shaped between the core and the part molds to give a structural part of the pipe. The core is removed from the structural parts, the structural parts being held on the part molds, and joining regions of the structural parts are oriented towards one another. The structural parts are joined to one another in the joining regions to form the pipe. The pipe is released from the part molds, wherein the part molds are moved away from one another after shaping in order to remove the core, and are then moved back together in order to orient the structural parts towards one another.

A method for making a yoga towel includes a step of preparing a towel with multiple apertures defined therethrough, a resilient plate placed on the towel; a step of placing the towel and the resilient plate between a top mold and a bottom mold which has cavities defined therethrough; a step of heating and softening the resilient plate and matching the top mold to the bottom mold, and a step of vacuuming to suck the softened resilient plate to form anti-slip protrusions on the second face of the towel via the apertures. The anti-slip protrusions are integrally formed with the towel and have elasticity.

A method for making a yoga towel includes a step of preparing a towel with multiple apertures defined therethrough, a resilient plate placed on the towel; a step of placing the towel and the resilient plate between a top mold and a bottom mold which has cavities defined therethrough; a step of heating and softening the resilient plate and matching the top mold to the bottom mold, and a step of vacuuming to suck the softened resilient plate to form anti-slip protrusions on the second face of the towel via the apertures. The anti-slip protrusions are integrally formed with the towel and have elasticity.