An actuator cap (1;50) for a fluid spray dispenser comprises a second body part (2) and a first body part (3). The first body part (3) is adapted for connection to a container for the fluid to be dispensed and incorporates a spray channel arrangement (4). The second body part (2) incorporates an actuator button (5) and is rotatable with respect to the first body part (3) from a first position in which the actuator button (5) is non-elevated into a second position in which the actuator button (5) is elevated and capable of depression to cause depression of a part (16) of the spray channel arrangement (4). The actuator button (4) defines a first cam profile (20) along which a first cam follower (22) defined by the first body part (3) travels to cause elevation or retraction of the actuator button (5) when the second body part (3) is rotated. The actuator button (5) also defines a second cam profile (23) that bears against said part (21) of the spray channel arrangement (4) such that when the actuator button (5) is in its elevated position and depressed the actuator button (5) depresses said second cam profile (23) and in turn depresses said part (21) of the spray channel arrangement (4) relative to the first body part (3) to dispense fluid from the container when in use. Preferably, the first and second body parts (3, 2) are individual, integrally moulded components that are snap-fitted together to assemble the actuator cap (1; 50).

Modular components of modular door lite frame systems are disclosed. In some cases, a modular door lite frame system includes matching first and second modular frames, one or more modular male alignment members, and one or more modular female alignment members. In some cases, the modular alignment members can be coupled to modular frames of various sizes. In some cases, the modular components can be formed by casting ABS between no more than two opposed mold portions.

A method for the design, manufacture, and assembly of modular lattice structures composed of cuboctahedron unit cells.

A method of monolithically forming a flip-top cap from a thermoplastic material and a flip-top cap for dispensing a flowable dental substance. The flip-top cap has a base from which a dropper nose protrudes and a closure. The base and the closure are hingedly connected to each other by a living hinge for pivoting between a closed position, in which the closure closes the dropper nose, and an open position, in which the dropper nose is uncovered from the closure. The method has the steps of injection molding the flip-top cap in the open position in an injection molding device and positioning the closure and the base toward the closed position while the flip-top cap is still the injection molding device.

A system for manufacturing a family of intake manifolds includes first and second intake molds. One of the first and second intake molds includes an outlet insert. A first intake manifold includes: a plenum chamber, a plenum chamber air inlet; a first number of intake runner passages; and the first number of outlets. Each of the outlets is fluidly connected to a corresponding one of the first number of intake runner passages. The second intake manifold includes: the plenum chamber; the plenum chamber air inlet; the first number of intake runner passages; and a second number of outlets. Each of the second number of outlets is fluidly connected to a corresponding one of the first number of intake runner passages. At least one of the first number of intake runner passages is not fluidly connected to any one of the second number of outlets of the second intake manifold.

The invention relates to a plastic vessel comprising a metal element which is accommodated its base, wherein the plastic vessel comprises a vessel element and a cover, such that the plastic vessel is formed in two pieces, wherein a recess is formed in the base of the vessel element, said recess being enclosed by the cover such a that a central closed region of the recess is provided, which accommodates the metal element, and wherein the vessel element and the cover are connected to one another thermoplastically under pressure. Moreover the invention relates to a method for producing a plastic vessel while using the thermoplastic properties of the plastic, and to the use of the vessel in interaction with a suitable means of transport and/or in a vehicle of any kind and/or for the usage by persons with reduced motor skills, perception, attention, and/or as a decorative element.

This disclosure provides a door lining upper base and a method of manufacturing the door lining upper base through injection molding of several sub-components. The door lining upper base is manufactured by separately injection molding a base substrate that forms the structural shape of the door lining upper base including aesthetic curvature, and first and second support structures that include attachment mechanism for connecting the door lining upper base to other aspects of the motor vehicle. In this way, each sub-component may be injection molded in a cost effective manner using a two-piece mold without the need for complex multi-part molds including side-sliders or lifters. The resulting door lining upper base therefore includes an aesthetic curvature, while still being manufactured in an efficient and cost effective manner.

An injection mold for molding a flip-top closure having a body portion and a lid attached to the body portion by a living hinge has first and second mold portions for defining first and second portions of the flip-top closure respectively, a lid closing tool for closing the lid of the flip-top closure on the body portion after a molding of the flip-top closure in the injection mold and before an ejection of the flip-top closure from the injection mold, and first and second linear actuators operatively connected to the lid closing tool for moving the lid closing tool about first and second axes respectively. The first and second linear actuators are controllable to move the lid closing tool along a lid closing path for closing the lid. An in-mold lid closing device and a method for making a flip-top closure are also disclosed.

A positive crankcase ventilation system for an internal combustion engine routes blowby gases into the intake of the engine. Because the blowby gases have about 12% water vapor, during cold-weather operation, the water vapor may freeze in the PCV valve or in the port that couples the PCV duct with the intake manifold. In situations in which the PCV duct is pointing toward the direction of flow of the intake gases, a hood or cap is placed over the end of the tube according to the present disclosure. It can be as simple as a 90-degree elbow or multiple openings in the cap. A centerline of the openings is perpendicular or at an obtuse angle with respect to the direction of flow in the duct so that the intake gases do not directly access the openings and cause freezing in the openings (or ports).

A vehicle door or tailgate, in particular for motor vehicles, with a frame which is formed as a support structure of the door or tailgate and is separate from an exterior and/or interior trim, wherein the frame is produced separately from plastic and/or a composite material, wherein the frame comprises at least two components which are connected to one another, and wherein the at least two components have connection means which comprise tongue and groove connections.