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.

A container that seals in a volume of material is provided. The container may be routinely opened, closed and material may be removed or added. A removable plate and a base define a maximum volume available for material when the container is sealed. A screen may be disposed between the plate and the base. The screen may optionally be comprised within the base, adhered to the base, or removable from the base. Features for enabling manipulation of the plate and/or screen are optionally provided.

A container and overcap assembly includes an open mouth container and an overcap with a built-in spout that is hinged to the overcap. The spout snaps shut inside the overcap when in a fully closed position and snaps into a fully open position as well. The spout accommodates a metered dose of product. In the fully open position, the spout seals the opening in the overcap to prevent product from exiting the container while a metered dose is dispensed from the open spout. The container assembly is particularly useful for containing and providing metered dispenses of dry products such as powders and granulated materials.

A flow selector configured for selectively or optionally regulating flow of liquid from a container is disclosed.

A liquid bottle or container, such as for liquid detergent, and corresponding cap and cup is disclosed for operation in a horizontal position with the cap and cup side wall substantially parallel to the ground, the cap and cup shape providing a built-in drip collector cavity positioned around a portion of the circumference or perimeter of the cap and cup rim on the open end of the cap. The cap and cup may be used to cover a nozzle or other valve dispenser during storage. The drip collector cavity has a volume sufficient to collect liquid residue remaining after normal use of the cap as a measuring and dispensing cup, and any post-use drops from the dispenser nozzle. Thus, the cap and cup of the present disclosure is dripless or nearly drip less. In an embodiment, at least a portion of the cap rim perimeter around which no built-in drip collector cavity is positioned is shaped as a pouring spout. In another embodiment, the area of the liquid container body which receives the cap is shaped to have an indent to accept the pouring spout, thus acting as an orientation key. In yet another embodiment, the drip collector cavity includes one or more radial partitions providing additional rigidity and support to the rim. In another alternative embodiment, the cap and cup shape provides a built-in drip collector cavity at the closed end of the cap. The side wall along the lowest elevation has a negative slope such that when the cap and cup is in the generally horizontal storage position covering the nozzle dispenser, the lowest point of elevation of the rim of the cap and cup is a higher elevation than the lowest point of elevation of the closed end of the cap and cup, thus resulting in collection of liquid residue at and/or near the closed end of the cap and cup.

In one embodiment, the present disclosure includes a cloud computer system for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands that may be performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.

In one embodiment, the present disclosure includes a cloud computer system for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands that may be performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.

A dispensing system (100) includes a pour cap (102) which may be connected with the neck of a container (900). The cap base includes a main deck (108), a dispensing spout (110) and a venting tube (112). A flow regulator is mounted on the underside of the main deck such that the flow regulator restricts flow through the opening of the dispensing spout. In some embodiments, the flow regulator is a hinged spring-loaded baffle plate (116). In some embodiments, the flow regulator is a gravity ball valve (316). A visual timing device (200) may be advantageously located on the pour cap (102) so that the timing device is easily visible to a user during operation or use of the dispensing system. The constant flow rate provided by the flow regulator allows the timing device to more precisely measure each pour regardless of how much fluid is in the bottle.

In one embodiment, a cloud computer system is disclosed for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.

In one embodiment, a cloud computer system is disclosed for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.