In a method and system for delivering fluid to a fluid consuming asset having a fluid tank, a first tank and a second tank are fluidically coupled and the second tank is pressurized. An inlet of a manifold is fluidically coupled to the second tank and an outlet of the manifold is coupled to a spigot. A first distal end of a fluid transporting mechanism is coupled to the spigot and a second distal end thereof is coupled to a hydraulic connector of a fill cap having a connection plate coupled to the fluid tank of the fluid consuming asset. The fill cap further comprises a probe and fluid flows from the first tank to the second tank, through the manifold and the hydraulic connector, through the probe and into the fluid tank of the fluid consuming asset.

In some embodiments, an apparatus includes a housing and a mount. The housing includes a cover portion and a base portion. The cover portion and the base portion define an interior. The housing defines an opening via which the interior can be accessed from a region external to the housing. The mount is coupled to the base portion and configured to maintain a position of a fillable component within the interior of the housing such that an elastomeric membrane of the fillable component is aligned with the opening defined by the housing and a reservoir of the fillable component is accessible by a needle via the opening and the elastomeric membrane.

A funnel is disclosed having an oil bottle securing portion and an adjustable conduit portion. The oil bottle securing portion is an open housing with converging side walls, and an end wall including a bottle securing rectangular groove along an upper edge. Seated within the open housing is a U-shaped stop that receives and abuts the top of a standard oil bottle, such that the neck of the oil bottle passes through the U-shaped stop but the shoulder of the bottle abuts the U-shaped stop. With a lower portion of the oil bottle disposed within the rectangular groove of the end wall and the neck of the oil bottle passing through the U-shaped stop, the oil from the bottle will empty into a frusto-conical reservoir at a first end of the funnel on the opposite side of the U-shaped stop and pass through the adjustable conduit.

A containment sump has a primary container and a secondary container which extends only partway up the outer wall of the primary container. This low-rise secondary container, in certain embodiments, cooperates with the primary container to create a hermetically sealed interstitial space encompassing the bottom of the primary container, including the lower portion of the upright containment wall and the container bottom. In alternative embodiments, the secondary container is a subassembly forming an interstitial space and joined as a subassembly to the primary container. More particularly, the upper end of the interstitial space may be below pipe or other conduit penetrations through the sidewall of the primary container. At the same time, any leak which may develop over the service life of the containment sump would be contained and detected within the bottom of the primary and/or secondary containers. Therefore, the present system combines the low cost and high reliability associated with single-wall penetrations through containment sump walls, while also offering the high level of environmental protection associated with double-wall spill containment.

A funnel is disclosed having an oil bottle securing portion and an adjustable conduit portion. The oil bottle securing portion is an open housing with converging side walls, and an end wall including a bottle securing rectangular groove along an upper edge. Seated within the open housing is a U-shaped stop that receives and abuts the top of a standard oil bottle, such that the neck of the oil bottle passes through the U-shaped stop but the shoulder of the bottle abuts the U-shaped stop. With a lower portion of the oil bottle disposed within the rectangular groove of the end wall and the neck of the oil bottle passing through the U-shaped stop, the oil from the bottle will empty into a frusto-conical reservoir at a first end of the funnel on the opposite side of the U-shaped stop and pass through the adjustable conduit.

A dispenser dispenses a consumable product from a container. The container is supported within a housing by a container holder. The container holder is vertically moveable within a movement range in the housing. A biasing structure biases the container holder upwardly. A sign is connected to move up and down with the container holder. An indicator associated with the sign is vertically fixed relative to the housing. When an amount of product remaining in the container reaches a low level, the biasing force of the biasing structure will lift the container holder, causing the indicator to be aligned with a portion of the sign that gives a visual cue to a user that the amount of product remaining is at a low level.

A conversion frame assembly configured to secure a fuel dispenser to a concrete pad and direct leaked fuel from the fuel dispenser into a sump at least partially embedded in the concrete pad. The conversion frame assembly includes a frame having a fluid passageway and a splash lip extending upward from the base plate and around the fluid passageway. The conversion frame assembly also includes a drainage tray configured to be coupled to the splash lip of the frame. When the drainage tray is coupled to the splash lip of the frame, an upper surface of the drainage tray defines a weir sloping inward and downward toward the fluid passageway in the base plate.

An idle fuel dispenser nozzle warning system that alerts a user to replace the nozzle in a nozzle boot of the fuel dispenser after fuel stops flowing through the nozzle and an idle fuel dispenser nozzle warning process for detecting inactivity by a nozzle removed from a nozzle boot of a fuel dispenser and activating a sensory alarm to remind a user to replace the nozzle in the nozzle boot of the fuel dispenser are disclosed. The system and process provide dynamic sensory warnings using sound and lights to get distracted people's attention to avoid wasted money, time, and environmental consequences of leaving the nozzle in the gas tank opening while driving away.

Methods are devices are provided for preventing fracture of a fluid-filled chamber or tank. In general an anti-fracture expansion device can be disposed internally within a fluid-filled chamber such that during a freeze event displaced fluid can compress or flow into the anti-fracture expansion device, thereby reducing the likelihood that the chamber will rupture. The internal disposition of the expansion device prevents it from interfering with other components that may be connected to or adjacent to the fluid chamber, thereby conserving space. In certain embodiments, the expansion device can have a dual function wherein it can act as a flow control valve in addition to functioning as an anti-fracture expansion device.

To prevent fuel from leaking to outside even when the fuel flows back at the time of an automatic stop operation during refueling. A fuel supply portion structure of a fuel supply pipe, including a tubular portion having a filler port and a connection port, a first flap mechanism which is provided on the filler port side of the tubular portion, a drain hole, and a drain hole on-off valve, wherein the drain hole on-off valve is disposed on a placement surface located at the lowermost side of a vehicle on an inner wall of a first inner diameter member, the placement surface is made of an inclined surface falling from the filler port side toward the connection port with respect to a horizontal plane of the vehicle, and a wall portion rising toward the filler port is provided on the filler port side of the inclined surface.