The invention relates to a system and method for management, control, and predictive maintenance in installations in damp rooms and fluid distribution networks, comprising the steps of: integrating an antenna (101, 101a...101e) inside at least one element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7), wherein said antenna (101, 101a, ..., 101e) is configured for receiving the signal of an electromagnetic field generated around same; and wherein said antenna (101, 101a...101e) is connected with at least one controlled electromagnetic field sensor (100) configured for generating an electric and magnetic field around said antenna (101, 101a, ..., 101e); continuously measuring the variations in the electric and magnetic field generated around the antenna (101, 101a, ..., 101e); establishing a behavioral pattern of the installation in an element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7); and selecting an action to be performed in the element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7) depending on the established behavioral pattern.

The invention relates to a system and method for management, control, and predictive maintenance in installations in damp rooms and fluid distribution networks, comprising the steps of: integrating an antenna (101, 101a...101e) inside at least one element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7), wherein said antenna (101, 101a, ..., 101e) is configured for receiving the signal of an electromagnetic field generated around same; and wherein said antenna (101, 101a...101e) is connected with at least one controlled electromagnetic field sensor (100) configured for generating an electric and magnetic field around said antenna (101, 101a, ..., 101e); continuously measuring the variations in the electric and magnetic field generated around the antenna (101, 101a, ..., 101e); establishing a behavioral pattern of the installation in an element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7); and selecting an action to be performed in the element installed in a damp room and/or fluid distribution network (3, 4, 5, 6, 7) depending on the established behavioral pattern.

An rinsing seat for a rimless toilet is disclosed. In one embodiment, the rinsing seat includes a large annular cavity for the purpose of storing and dispensing rinse water. In another embodiment, the rinsing seat includes a smaller annular cavity for the purpose of dispensing rinse water from a pressurized line. Outlet nozzles arranged about the circumference of the rinsing seat and designed to dispense rinse water at varying angles relative to the rinsing seat are disclosed. Rinsing seat supports, hinge assemblies, and seat sensors which offer additional functionality to the rinsing seat are also disclosed and claimed herein.

This disclosure relates to new methods and compositions for dispensing multiple compositions into a plurality of containers or atmospheres. In one embodiment, this disclosure pertains to treating and preventing offensive odors arising from toilets.

A non-invasive system and method for disease detection and real-time monitoring of organ health wherein the changes in the electrical properties of urine samples are studied over time in the presence or absence of interacting chemicals for qualitative and quantitative estimation of urinary analytes. The system has two components—a test platform and a reader. The test platform is integrated with electrodes and chemicals, which interact with urine to detect the biomarker of the disease and quantify the analyte. The changes in the electrical properties serve as an electrical signature for a particular analyte. This electrical signal from the test platform is relayed to an electronic reader that receives, processes, and analyzes the data for single test detection or continuous monitoring. The reader stores the information that can then be coupled to a readout system or transmitted by wired or wireless mechanisms to any electronic platform in real-time.

A non-invasive system and method for disease detection and real-time monitoring of organ health wherein the changes in the electrical properties of urine samples are studied over time in the presence or absence of interacting chemicals for qualitative and quantitative estimation of urinary analytes. The system has two components—a test platform and a reader. The test platform is integrated with electrodes and chemicals, which interact with urine to detect the biomarker of the disease and quantify the analyte. The changes in the electrical properties serve as an electrical signature for a particular analyte. This electrical signal from the test platform is relayed to an electronic reader that receives, processes, and analyzes the data for single test detection or continuous monitoring. The reader stores the information that can then be coupled to a readout system or transmitted by wired or wireless mechanisms to any electronic platform in real-time.

The invention relates to free floating automated toilet bowl cleaning devices that dispense a volatile composition (e.g., a fragrance) into air surrounding the toilet and dispense a cleaning composition (e.g., hypohalite bleach) into toilet tank water on which the device freely floats. The device includes a first compartment for housing the volatile composition. The first compartment is permeable to air, with the permeable portion of the first compartment positioned above a water line when the device is floated. The device includes a second compartment for housing the cleaning composition. The second compartment includes one or more inlets through the device body to allow fluid communication with the liquid on which the device floats during use. A floatation member is positioned above the second compartment (e.g., between the first and second compartments).

The present invention provides a device for collecting liquid and a smart toilet comprising the same. The device comprises a fixing support, a swinging mechanism, a suction tube assembly and a pump body mechanism; the suction tube assembly (9) comprises a slide rail component and a retractable suction tube component disposed therein, one end of the slide rail component is connected to the swinging mechanism; the suction tube component comprises a suction tube internally provided with a cavity and an opening disposed above the cavity, and a first conduit disposed in the suction tube one end of the first conduit is inserted in the cavity, the other end of the first conduit is connected to the pump body mechanism. The fixing support is fixedly connected to the toilet body; the suction tube component swings towards the center of the toilet under the effect of the swinging mechanism, the suction tube component is used for receiving the urine. The device further comprises a liquid-level sensing mechanism for monitoring the amount of the urine in the cavity in real time and controlling the start and stop of the pump body mechanism according to the amount of the urine. The device takes the urine sucked in the air as a sample for health analysis, avoiding the problem of cross-contamination caused by sucking the urine from the inside surface of the toilet.

The present invention provides a device for collecting liquid and a smart toilet comprising the same. The device comprises a fixing support, a swinging mechanism, a suction tube assembly and a pump body mechanism; the suction tube assembly (9) comprises a slide rail component and a retractable suction tube component disposed therein, one end of the slide rail component is connected to the swinging mechanism; the suction tube component comprises a suction tube internally provided with a cavity and an opening disposed above the cavity, and a first conduit disposed in the suction tube one end of the first conduit is inserted in the cavity, the other end of the first conduit is connected to the pump body mechanism. The fixing support is fixedly connected to the toilet body; the suction tube component swings towards the center of the toilet under the effect of the swinging mechanism, the suction tube component is used for receiving the urine. The device further comprises a liquid-level sensing mechanism for monitoring the amount of the urine in the cavity in real time and controlling the start and stop of the pump body mechanism according to the amount of the urine. The device takes the urine sucked in the air as a sample for health analysis, avoiding the problem of cross-contamination caused by sucking the urine from the inside surface of the toilet.

A toilet bowl includes a main body defining a urine and feces transfer passage; and a collection member arranged in a first direction from the main body, wherein the main body comprises a urine and feces transfer surface and a urine and feces separation surface arranged in the first direction, wherein the urine and feces separation surface extends along a circumference of the urine and feces transfer passage, and separates mixed urine and feces transferred from the urine and feces transfer surface into liquid urine and feces and solid urine and feces, and wherein the collection member accommodates each of the liquid urine and feces and the solid urine and feces.