An article of footwear having a heel region with a posterior end of the article of footwear, a mid-foot region, and a forefoot region with an anterior end of the article of footwear; a lateral side, and a medial side opposite the lateral side; an upper; a sole structure, the sole structure coupled to the upper, and wherein the sole structure has; a cushioning element disposed in the heel region, the cushioning element having a first tube and a second tube, wherein each of the first tube and the second tube extend from the lateral side of the article of footwear to the medial side of the article of footwear, wherein the first tube includes a contained fluid volume at a first pressure, and the second tube includes a contained fluid volume at a second pressure, wherein the first pressure and the second pressure are equal to one another.

A method of forming a cushioning element. The method including placing a first sheet adjacent to an outer surface of a first mold portion, the first mold portion including a first mold cavity. The method including pressing a portion of the first sheet into the first mold portion and into the first mold cavity with a forming tool, wherein at least a portion of the forming tool is extended into the first mold cavity. The method including applying negative pressure to the first mold cavity to draw the portion of the first sheet into the first mold cavity, and joining a second sheet to the first sheet to form the cushioning element.

A method of forming a cushioning element. The method including placing a first sheet adjacent to an outer surface of a first mold portion, the first mold portion including a first mold cavity. The method including pressing a portion of the first sheet into the first mold portion and into the first mold cavity with a forming tool, wherein at least a portion of the forming tool is extended into the first mold cavity. The method including applying negative pressure to the first mold cavity to draw the portion of the first sheet into the first mold cavity, and joining a second sheet to the first sheet to form the cushioning element.

An article of footwear having a heel region including a posterior end, a mid-foot region, and a forefoot region including an anterior end. The article of footwear having a lateral side, and a medial side opposite the lateral side; an upper; and a sole structure coupled to the upper. The sole structure has a first cushioning element, having a plurality of first tubes and a plurality of first web areas. Adjacent first tubes are connected to one another by a respective first web area of the plurality of first web areas. The sole structure also having a second cushioning element, having a plurality of second tubes and a plurality of second web areas. Adjacent second tubes are connected to one another by a respective web area of the second plurality of web areas.

An article of footwear having a heel region including a posterior end, a mid-foot region, and a forefoot region including an anterior end. The article of footwear having an upper extending from the heel region to the forefoot region and a sole structure coupled to the upper. The sole structure further has a first cushioning element having a first tube, a second tube, a third tube, and a fourth tube, and an outsole layer extending from the posterior end to the anterior end. The outsole layer is configured to directly receive a portion of the first cushioning element, and the outsole layer forms a ground-contacting surface of the article of footwear.

A product [11] includes a foldable clamshell-type housing [10] folded to a closed position to contain a pre-formed sensor pad [17] that was formed in situ therein when the housing [10] was in an open position, prior to closing. The housing [10] has an enclosed volume [12] bounded by relatively thin and flexible walls [23, 34], and outwardly extending tabs [18] which facilitate opening. This structure enables the user to easily open the housing [10] to remove the sensor pad [17], a cured silicone composition, by pushing inward on an outer surface of the outer wall [34] of a base section [15] of the housing [10]. This product [11] reduces the amount of manipulation needed to place the sensor pad [17] in a desired position, for example, during installation of a rain sensor system for a vehicle windshield.

A product [11] includes a foldable clamshell-type housing [10] folded to a closed position to contain a pre-formed sensor pad [17] that was formed in situ therein when the housing [10] was in an open position, prior to closing. The housing [10] has an enclosed volume [12] bounded by relatively thin and flexible walls [23, 34], and outwardly extending tabs [18] which facilitate opening. This structure enables the user to easily open the housing [10] to remove the sensor pad [17], a cured silicone composition, by pushing inward on an outer surface of the outer wall [34] of a base section [15] of the housing [10]. This product [11] reduces the amount of manipulation needed to place the sensor pad [17] in a desired position, for example, during installation of a rain sensor system for a vehicle windshield.

A method of making a multilayer sheet includes: forming a substrate including a substrate first surface and a substrate second surface; applying a conductive layer including a base and a conductive coating to the substrate first surface; and applying an ultraviolet cured coating layer to a surface of the conductive layer opposite that in contact with the substrate second surface, wherein the ultraviolet cured coating layer comprises a multifunctional acrylate oligomer and an acrylate monomer; pressing the substrate, conductive layer, and ultraviolet cured coating layer together to form a stack; heating the stack; activating the ultraviolet cured coating layer with an ultraviolet radiation source; and removing the base from the stack leaving a conductive multilayer sheet; wherein the ultraviolet cured coating layer remains adhered to the conductive layer.

A method of making a multilayer sheet includes: forming a substrate including a substrate first surface and a substrate second surface; applying a conductive layer including a base and a conductive coating to the substrate first surface; and applying an ultraviolet cured coating layer to a surface of the conductive layer opposite that in contact with the substrate second surface, wherein the ultraviolet cured coating layer comprises a multifunctional acrylate oligomer and an acrylate monomer; pressing the substrate, conductive layer, and ultraviolet cured coating layer together to form a stack; heating the stack; activating the ultraviolet cured coating layer with an ultraviolet radiation source; and removing the base from the stack leaving a conductive multilayer sheet; wherein the ultraviolet cured coating layer remains adhered to the conductive layer.

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.