A fluid treatment and disposal system includes a sink, having a basin, a sink drain inlet, and a sink drain trap. An open cavity is disposed behind a rearward wall of the sink basin, between a top portion of the sink and the sink drain trap. A curved transition surface receives fluid entering the sink. Embodiments of the drain are shaped to promote the evacuation of fluid from the basin while limiting turbulence. An exhaust port fluidly coupled with the open cavity evacuates the open cavity and surrounding environment. Embodiments optionally associate one or more of the following with the open cavity: Ultra-Violet (UV) Germicidal Lights, and Ozone water, copper-silver ionization, and/or sanitizing agent injection systems.

A fluid treatment and disposal system includes a sink, having a basin, a sink drain inlet, and a sink drain trap. An open cavity is disposed behind a rearward wall of the sink basin, between a top portion of the sink and the sink drain trap. A curved transition surface receives fluid entering the sink. Embodiments of the drain are shaped to promote the evacuation of fluid from the basin while limiting turbulence. An exhaust port fluidly coupled with the open cavity evacuates the open cavity and surrounding environment. Embodiments optionally associate one or more of the following with the open cavity: Ultra-Violet (UV) Germicidal Lights, and Ozone water, copper-silver ionization, and/or sanitizing agent injection systems.

An approach is disclosed for preventing splashing of a liquid under a splashing area from a liquid source utilizing a barrier. The barrier includes a base, a top side of the base, a bottom side of the base, a first side of the base, a second side of the base, suction cups integrated into the bottom side of the base, a first angled foot is attached to the first side of the base, and a second angled foot is attached to the second side of the base. The first angled foot and the second angled foot are designed angled to allow a limited compression of the suction cups. When the barrier is placed on the splashing are, the suction cups are compressed to adhere to the area to form a seepage guard by the first angled foot preventing the liquid from seeping under the first angled foot.

An approach is disclosed for preventing splashing of a liquid under a splashing area from a liquid source utilizing a barrier. The barrier includes a base, a top side of the base, a bottom side of the base, a first side of the base, a second side of the base, suction cups integrated into the bottom side of the base, a first angled foot is attached to the first side of the base, and a second angled foot is attached to the second side of the base. The first angled foot and the second angled foot are designed angled to allow a limited compression of the suction cups. When the barrier is placed on the splashing are, the suction cups are compressed to adhere to the area to form a seepage guard by the first angled foot preventing the liquid from seeping under the first angled foot.

A sink includes a basin including a bottom wall and adjoining side walls which delimit a receiving space. An insert plate separate from the basin is inserted into the receiving space, and a lifting apparatus moves the insert plate relative to the basin. The lifting apparatus includes a lifting unit with a lifting device to move the insert plate in a vertical direction. The lifting apparatus includes a tilting device configured to perform a tilting movement of the insert plate relative to a horizontal plane.

A sink includes a basin including a bottom wall and adjoining side walls which delimit a receiving space. An insert plate separate from the basin is inserted into the receiving space, and a lifting apparatus moves the insert plate relative to the basin. The lifting apparatus includes a lifting unit with a lifting device to move the insert plate in a vertical direction. The lifting apparatus includes a tilting device configured to perform a tilting movement of the insert plate relative to a horizontal plane.

Embodiments of the present disclosure are directed to an assembly that drains liquid from kitchen equipment, in particular commercial kitchen equipment, where there otherwise is not a drain. More specifically, the disclosed system provides an assembly that can be mounted near the commercial kitchen equipment to drain liquids, such as water, from the equipment without the need to add in a floor drain. The assembly includes an angled floor within a reservoir to force the liquid through an aperture and a clip assembly so that the reservoir may be mounted directly to or near the kitchen equipment.

A lavatory system includes a basin having a water collecting area having a back wall, a bottom wall, and a front wall. The back wall of the water collecting area is proximate the wall on which the lavatory system is mounted. Further, an opening may extend through the front wall. The lavatory system also includes a hand dryer having a blower located below the water collecting area and a first plenum having an input and an output. The input is connected to the blower to receive a first air flow from the blower, and the output is aligned with the opening in the front wall of the water collecting area to deliver the first air flow from the front wall over the water collecting area.

A lavatory system includes a basin having a water collecting area having a back wall, a bottom wall, and a front wall. The back wall of the water collecting area is proximate the wall on which the lavatory system is mounted. Further, an opening may extend through the front wall. The lavatory system also includes a hand dryer having a blower located below the water collecting area and a first plenum having an input and an output. The input is connected to the blower to receive a first air flow from the blower, and the output is aligned with the opening in the front wall of the water collecting area to deliver the first air flow from the front wall over the water collecting area.

A fluid delivery apparatus includes a spout, an active sensor, and a passive sensor. The active sensor is configured to detect the presence of a user adjacent the spout when enabled. The passive sensor is configured to define a sensing field in an area near the spout and also to detect a presence of a user. A controller is coupled to the passive sensor and the active sensor. The controller is programmed to detect the presence of a user in the sensing field based on an output signal from the active sensor in response to detecting the presence of the user in the sensing field with the passive sensor, thereby reducing the amount of power used by the active sensor.