Abstract: An exhaust conduit for neutralizing condensate from high efficiency gas storage water heaters is provided. The exhaust conduit includes an inlet configured to be coupled to an exhaust outlet of the heater, an outlet configured to be coupled to an exhaust vent, and a condensate chamber having an interior in fluidic communication with the inlet and the outlet. The condensate chamber has a lower portion configured to receive a neutralizer and an upper portion having a service port configured to provide access to the lower portion of the condensate chamber. The condensate chamber further includes a fluid outlet for draining the neutralized condensate via a drain line. The exhaust conduit has one or more ridges disposed in the chamber that are arranged to define a channel for directing condensate from the inlet across the neutralizer toward the fluid outlet.

Abstract: A titanium alloy comprising Al 4.78 to 6.44 wt. %; V 3.65 to 5.15 wt. %; Mo 1.32 to 3.58 wt. %; Cr 0.75 to 2.28 wt. %; Fe 0.00 to 0.42 wt. %; C 0.00 wt. % to 0.10 wt. %; S 0.00 wt. % to 0.10 wt. %; N up to 500 ppm; O up to 2000 ppm and H up to 150 ppm; the balance being Ti and incidental elements and unavoidable impurities. Such a titanium alloy is useful for manufacturing gas turbine engine components including turbine blades and stators.

Abstract: Disclosed are methods for augmenting progressive meter information presented in association with a gaming device. The methods include controlling a camera on a mobile device using an augmented reality gaming assistance component and enabling a user to employ the camera to capture an image of a game screen display, the image including one or more progressive meters associated with a respective progressive award. The captured image is sent via a network to a server that, for each of one or more progressive meters, determines a location of the progressive meters within the captured image, determines a value for each associated progressive award based on the captured image at each respective location, and determines a progressive rating for the associated progressive award based on the value. Content based on the one or more progressive ratings is received at the mobile device and displayed to the user via a display.

Abstract: A leg restraint includes a buckle portion in the form of a buckle frame attached to a strap portion. The strap portion includes a section of a loop fabric of a hook-and-loop fastener and a section of a hook fabric of the hook-and-loop fastener. The buckle portion is pliable and resilient and configured to accept the strap within the loop of the buckle frame. The strap is configured to be fed through the buckle frame and looped back on itself to allow the loop portion of the strap to contact the hook portion of the strap, thereby fastening the two strap portions together through the engagement of the hook-and-loop fastener. The strap may have the hook and loop fabric exposed on both faces of the strap such that the strap may be looped back in either direction for fastening.

Abstract: A weeding device provides leverage for pulling a deeply-rooted plant from soil without requiring excessive foot pressure for operation. A handle is attached to a weeder head having a first fork extending away from the end of the handle. A rotating jaw is mounted to the weeder head, and has a second fork displaced from the first fork when the second fork are parallel. The weeding device has a step for applying foot pressure to insert the first and second forks in the soil prior. A lever extension of the rotating jaw on an opposite side of the handle contacts the soil when the forks are fully inserted in the soil, and as the handle is rotated toward the soil a tip of the second fork inclines toward a tip of the first fork to close the first fork and the second fork around a plant.

Abstract: Disclosed is a wet wipe, for example, a dispersible wet wipe. The wet wipe may include a base sheet comprising short length fibers; a dispersible binding agent reinforcing the base sheet; and a wetting lotion. The dispersible binding agent may be configured to bind the fibers of the base sheet when the dispersible wiper includes liquid at an amount of at most 400 wt % from the weight of the base sheet and to disperse in excess water if the amount of the water exceeds 500 wt %.

Abstract: Disclosed is a wet wipe, for example, a dispersible wet wipe. The wet wipe may include a base sheet comprising short length fibers; a dispersible binding agent reinforcing the base sheet; and a wetting lotion. The dispersible binding agent may be configured to bind the fibers of the base sheet when the dispersible wipe includes liquid at an amount of at most 400 wt % from the weight of the base sheet and to disperse in excess water if the amount of the water exceeds 500 wt %.

Abstract: Disclosed is a wet wipe, for example, a dispersible wet wipe. The wet wipe may include a base sheet comprising short length fibers; a dispersible binding agent reinforcing the base sheet; and a wetting lotion. The dispersible binding agent may be configured to bind the fibers of the base sheet when the dispersible wiper includes liquid at an amount of at most 400 wt % from the weight of the base sheet and to disperse in excess water if the amount of the water exceeds 500 wt %.

Abstract: A method of making a resilient tampon includes the steps of providing binder fibers having an average fiber length of at least 35 mm; combining the binder fibers to form a loose fleece; activating the binder fibers; and compressing a portion of the loose fleece into a pledget after activating the binder fibers. A resilient tampon includes 70 wt % to 95 wt % absorbent fibers and 5 wt % to 30 wt % bicomponent binder fibers. The binder fibers have an average fiber length greater than 35 mm.

Abstract: A device comprising an array of transistors, including: patterned conductive layers located at lower and upper levels in a stack of layers on a substrate, which patterned conductive layers define gate conductors and source-drain electrodes of the array of transistors; wherein the stack of layers further comprises a dielectric layer below said lower level, and a further patterned conductive layer below said dielectric layer; and wherein said further patterned conductive layer both provides an electrical function in said array of transistors via said dielectric layer, and defines openings via which the dielectric layer serves to increase the strength of adhesion between the device substrate and the patterned conductive layer at said lower level.

Abstract: A method of making a resilient tampon includes the steps of providing binder fibers having an average fiber length of at least 35 mm; combining the binder fibers to form a loose fleece; activating the binder fibers; and compressing a portion of the loose fleece into a pledget after activating the binder fibers. A resilient tampon includes 70 wt % to 95 wt % absorbent fibers and 5 wt % to 30 wt % bicomponent binder fibers. The binder fibers have an average fiber length greater than 35 mm.

Abstract: A device comprising an array of transistors, including: patterned conductive layers located at lower and upper levels in a stack of layers on a substrate, which patterned conductive layers define gate conductors and source-drain electrodes of the array of transistors; wherein the stack of layers further comprises a dielectric layer below said lower level, and a further patterned conductive layer below said dielectric layer; and wherein said further patterned conductive layer both provides an electrical function in said array of transistors via said dielectric layer, and defines openings via which the dielectric layer serves to increase the strength of adhesion between the device substrate and the patterned conductive layer at said lower level.

Abstract: A method of making a resilient tampon includes the steps of providing binder fibers having an average fiber length of at least 35 mm; combining the binder fibers to form a loose fleece; activating the binder fibers; and compressing a portion of the loose fleece into a pledget after activating the binder fibers. A resilient tampon includes 70 wt % to 95 wt % absorbent fibers and 5 wt % to 30 wt % bicomponent binder fibers. The binder fibers have an average fiber length greater than 35 mm.

Abstract: We describe an electronic document reading device comprising: a wireless remote content connection; a physical user interface for receiving device control commands from a user; non-volatile data storage; a non-volatile electrophoretic display screen; and a device controller.

Abstract: A method of making a resilient tampon includes the steps of providing binder fibers having an average fiber length of at least 35 mm; combining the binder fibers to form a loose fleece; activating the binder fibers; and compressing a portion of the loose fleece into a pledget after activating the binder fibers. A resilient tampon includes 70 wt % to 95 wt % absorbent fibers and 5 wt % to 30 wt % bicomponent binder fibers. The binder fibers have an average fiber length greater than 35 mm.

Abstract: An absorbent composite disposed in an absorbent article between a topsheet and a backsheet is presented, the absorbent composite including a first intake layer disposed between the topsheet and the backsheet, and a retention layer disposed between the topsheet and the backsheet, wherein one of the first intake layer and the retention layer includes a resilient coform material. When the first intake layer includes a resilient coform material, the retention layer includes one of a high-density, hydrogen-bonded, fluff/superabsorbent polymer material, a spunlace material, a superabsorbent polymer/adhesive composite material, and a foam material. The absorbent composite can further include a distribution layer disposed between the topsheet and the backsheet, the distribution layer including one of a meltblown microfiber material, a spunlace material, and a foam material.

Abstract: An article comprises a stretchable absorbent composite (30) that includes a quantity of superabsorbent particles (32) which are operatively contained within a matrix of elastomeric polymer fibers (34). In particular aspects, the composite article can include at least about 60 wt % of the superabsorbent particles and not more than about 40 wt % of the elastomeric polymer fibers, based on a total weight of the composite. In other aspects, the composite article can provide a high stretchability. Additional aspects can provide a low shake-out. Particular configurations can, for example, provide a stretchability value of at least about 30%. Additional aspects can include a configuration that provides a shake-out value of not more than about 2%. In further aspects, the absorbent composite can include superabsorbent particles having a coating of treatment-material that is thermally processible. Additional aspects can include a treatment-material which is water soluble.