An environmentally-friendly, anti-contamination suction-nozzle beverage cup cover includes a cover body connected to a beverage cup and formed with a suction nozzle mounting chamber at the top of the cover body, a tube insertion hole formed in the mounting chamber, a suction nozzle disposed in the tube insertion hole, a swing sleeve provided outside the suction nozzle and formed with a swing pin fitted into the swing holes, swing holes formed in both sides of the mounting chamber, a connecting ear formed at one side of the cover body, a clamp and a safety catch disposed on and fixed with the connecting ear via a shaft, a return ejector spring disposed in the clamp, a shield disposed on the cover body and in contact with the head of the suction nozzle. The head of the shield is formed with a clamp rib that matches the clamp.

A fluid container having a body, a handle arranged in a top section of the body, a flow trigger in the handle, and a safety trigger that interacts with the flow trigger and prevents activation of the flow trigger. A vent assembly is arranged in the body and is configured to b activated by the safety trigger to vent the body. A spout assembly is movably coupled to the body and rotates between a use position and a storage position. A first valve opens as the spout assembly is moved from the storage position to the use position and a second valve is arranged upstream of the first valve to control fluid flow into the spout assembly. A linkage mechanism is arranged between th flow trigger and the second valve and configured to open the second valve when the flow trigger is activated and the safety trigger is released.

A fluid container having a body, a handle arranged in a top section of the body, a flow trigger in the handle, and a safety trigger that interacts with the flow trigger and prevents activation of the flow trigger. A vent assembly is arranged in the body and is configured to b activated by the safety trigger to vent the body. A spout assembly is movably coupled to the body and rotates between a use position and a storage position. A first valve opens as the spout assembly is moved from the storage position to the use position and a second valve is arranged upstream of the first valve to control fluid flow into the spout assembly. A linkage mechanism is arranged between th flow trigger and the second valve and configured to open the second valve when the flow trigger is activated and the safety trigger is released.

The disclosure relates to a portable fuel container system which can facilitate extracting substantially all of the contents contained therein, without having to physically manipulate the container to do so, thereby minimizing spillage and waste. Embodiments of the fuel container system can include a fuel container enclosing a fluid cavity and a fluid dispenser. A collection channel may be recessed in the base section of the container and configured to gravitationally draw fluid to an end of the channel having an aperture, which forms a low point of the fluid cavity. A fluid dispenser can be coupled to the aperture and be in fluid communication with the cavity. The dispenser can include a valve and flexible conduit, allowing the user to position the dispenser to a desired location before activating the flow of fluid.

A fluid container having a body, a handle arranged in a top section of the body, a flow trigger in the handle, and a safety trigger that interacts with the flow trigger and prevents activation of the flow trigger. A vent assembly is arranged in the body and is configured to b activated by the safety trigger to vent the body. A spout assembly is movably coupled to the body and rotates between a use position and a storage position. A first valve opens as the spout assembly is moved from the storage position to the use position and a second valve is arranged upstream of the first valve to control fluid flow into the spout assembly. A linkage mechanism is arranged between the flow trigger and the second valve and configured to open the second valve when the flow trigger is activated and the safety trigger is released.

A fluid container having a body, a handle arranged in a top section of the body, a flow trigger in the handle, and a safety trigger that interacts with the flow trigger and prevents activation of the flow trigger. A vent assembly is arranged in the body and is configured to b activated by the safety trigger to vent the body. A spout assembly is movably coupled to the body and rotates between a use position and a storage position. A first valve opens as the spout assembly is moved from the storage position to the use position and a second valve is arranged upstream of the first valve to control fluid flow into the spout assembly. A linkage mechanism is arranged between the flow trigger and the second valve and configured to open the second valve when the flow trigger is activated and the safety trigger is released.

A lid-spout assembly for a package intended to contain a pourable product and having a main body including a designated pour opening through which the pourable product can be poured, in use; the lid-spout assembly including a spout having a pouring outlet fluidly connectable with the designated pour opening; and a lid configured to be coupled to the spout to selectively close and open the pouring outlet; the spout including: a base frame configured to couple the spout to the main body about the designated pour opening and having a first wall configured to face, in use, the inner space of the main body, and a collar carrying the pouring outlet and protruding from the base frame; the base frame including a plurality of recesses obtained on the first wall.

Disclosed is an environmentally-friendly, anti-contamination suction-nozzle beverage cup cover, comprising a cover body (1), with the lower part of the cover body (1) being connected to a beverage cup (2), the top of the cover body (1) being formed with a suction nozzle mounting chamber (4), a tube insertion hole (5) being formed in the suction nozzle mounting chamber (4), and a suction nozzle (7) being disposed in the tube insertion hole (5), characterized in that a swing sleeve (8) is provided outside the suction nozzle (7) made of silicone, swing holes (9) are formed in both sides of the mounting chamber (4), the swing sleeve (8) is formed with a swing pin (10) fitted into the swing holes (9), a connecting ear (11) is formed at one side of the cover body (1), a clamp (12) and a safety catch (13) are disposed on the connecting ear (11), the clamp (12) and the safety catch (13) are fixed with the connecting ear (11) via a small shaft (14), a return ejector spring (15) is disposed in the clamp (12), a shield (17) is disposed on the cover body (1), the inner wall of the shield (17) is in contact with the head of the suction nozzle, the head (20) of the shield (17) is formed with a clamp rib (18), and the clamp rib (18) matches the clamp (12). Bacterial contamination can be avoided when the cup cover is opened and closed.

A portable beverage container includes a container body defining an interior adapted to store a liquid, and a lid assembly that includes a lid housing removably coupled to the container body and a spout coupled to the lid housing and movable between a stowed configuration and a dispensing configuration, the spout defining a fluid passageway in selective fluid communication with the interior of the container body. The lid assembly also includes a seal housing carrying a sealing element, the seal housing movably coupled to the lid housing between an in-use position, wherein the seal housing engages the spout such that the sealing element controls fluid flow through the fluid passageway of the spout, and a cleaning position, wherein the seal housing is spaced from the spout to permit cleaning of the sealing element.

A lid for a liquid container has a lid wall with a perimeter, a top side surface, and an underside surface. The lid has an anti-glug device carried on the lid wall and positioned to coincide with a dispensing orifice in the lid wall. The anti-glug device has a channel that partly circumferentially surrounds the dispensing orifice. Terminal ends of the channel define a circumferential gap therebetween. One or more air vents are formed axially through a part of the channel and are disposed circumferentially opposite the circumferential gap.