A device that conserves water and repurposes liquid human waste for use in a toilet is described herein. In some examples, the device includes a funnel and urine collection hat with a drainage hole. In some further examples, the device includes a gravity filter and a collection receptacle. In still further examples, the device includes a collection hat and a tube.

Exemplary embodiments of a pet toilet are provided. A pet toilet is provided having a base, a standing surface provided on the base configured to allow a pet to stand on the standing surface, a first flush mechanism to provide water for flushing the standing surface, a rim tube connected to the first flush mechanism configured to provide water from the first flush mechanism to the standing surface, and at least one water outlet disposed on the rim tube for providing water from the first flush mechanism to the standing surface. The flush mechanism can be an automatic flush mechanism triggered by one or more motion sensors. The standing surface can have a concave surface.

Exemplary embodiments of a pet toilet are provided. A pet toilet is provided having a base, a standing surface provided on the base configured to allow a pet to stand on the standing surface, a first flush mechanism to provide water for flushing the standing surface, a rim tube connected to the first flush mechanism configured to provide water from the first flush mechanism to the standing surface, and at least one water outlet disposed on the rim tube for providing water from the first flush mechanism to the standing surface. The flush mechanism can be an automatic flush mechanism triggered by one or more motion sensors. The standing surface can have a concave surface.

A health monitoring toilet system collects urine in a toilet system which may resemble a traditional water toilet. The toilet system may include a urine capture basin for collecting urine as a user urinates as with a traditional toilet. The urine capture basin may include a urine entry aperture which is an orifice leading into a urine sample cell. A fiber optic spectrometer may analyze the urine in the urine sample cell to collect relevant health data. The system may include a controller which may store and analyze spectral data and compile longitudinal data over time. The system may be in connection with other such systems to compare the analysis of a user's urine with those of other users stored in other such health monitoring toilet systems.

A health monitoring toilet system collects urine in a toilet system which may resemble a traditional water toilet. The toilet system may include a urine capture basin for collecting urine as a user urinates as with a traditional toilet. The urine capture basin may include a urine entry aperture which is an orifice leading into a urine sample cell. A fiber optic spectrometer may analyze the urine in the urine sample cell to collect relevant health data. The system may include a controller which may store and analyze spectral data and compile longitudinal data over time. The system may be in connection with other such systems to compare the analysis of a user's urine with those of other users stored in other such health monitoring toilet systems.

The present disclosure describes a method of detecting a drug marker in urine a urine sample using a toilet. The drug markers are fluorophores each of which emits a unique fluorescence spectra. Accordingly, the method does not detect the drug but rather, the drug marker. The drug marker may include quantum dots which may be functionalized by connecting the quantum dot to a biomolecule. The biomolecule may be cleavable by a peptidase, a protease, or a nuclease to release the drug. Alternatively, the composition may include a liposome carrier. A user who has consumed the drug composition urinates into the toilet and a urine sample is captured. The toilet includes a mechanism for fluid handling which diverts urine into a fluorescence spectrometer. The fluorescence spectrometer screens the urine for drug markers based on their unique fluorescent spectra.

The present disclosure describes a method of detecting a drug marker in urine a urine sample using a toilet. The drug markers are fluorophores each of which emits a unique fluorescence spectra. Accordingly, the method does not detect the drug but rather, the drug marker. The drug marker may include quantum dots which may be functionalized by connecting the quantum dot to a biomolecule. The biomolecule may be cleavable by a peptidase, a protease, or a nuclease to release the drug. Alternatively, the composition may include a liposome carrier. A user who has consumed the drug composition urinates into the toilet and a urine sample is captured. The toilet includes a mechanism for fluid handling which diverts urine into a fluorescence spectrometer. The fluorescence spectrometer screens the urine for drug markers based on their unique fluorescent spectra.

Implementations of a self-cleaning toilet cleaner are provided. In some implementations, the self-cleaning toilet cleaner may comprise a housing, one or more reservoirs, a toilet opener, one or more exterior brushes, and one or more bowl brushes. In some implementations, the self-cleaning toilet cleaner may also comprise one or more lid brushes, one or more seat brushes, one or more fluid lines, and one or more fluid pumps. In some implementations, the self-cleaning toilet cleaner may also comprise one or more blowers, one or more operation pads, one or more operation motors, one or more sensors, and a computer system.

In some implementations, a method of using the self-cleaning toilet cleaner may comprise receiving a toilet into the self-cleaning toilet cleaner, cleaning one or more portions of the toilet with the respective brushes, and applying a fluid to further clean the portions of the toilet. In some implementations, the method may also comprise applying a fluid to rinse the one or more portions of the toilet, drying the one or more portions of the toilet by blowing air on the portions with the blower, and releasing the toilet from the self-cleaning toilet cleaner.

Implementations of a self-cleaning toilet cleaner are provided. In some implementations, the self-cleaning toilet cleaner may comprise a housing, one or more reservoirs, a toilet opener, one or more exterior brushes, and one or more bowl brushes. In some implementations, the self-cleaning toilet cleaner may also comprise one or more lid brushes, one or more seat brushes, one or more fluid lines, and one or more fluid pumps. In some implementations, the self-cleaning toilet cleaner may also comprise one or more blowers, one or more operation pads, one or more operation motors, one or more sensors, and a computer system.

In some implementations, a method of using the self-cleaning toilet cleaner may comprise receiving a toilet into the self-cleaning toilet cleaner, cleaning one or more portions of the toilet with the respective brushes, and applying a fluid to further clean the portions of the toilet. In some implementations, the method may also comprise applying a fluid to rinse the one or more portions of the toilet, drying the one or more portions of the toilet by blowing air on the portions with the blower, and releasing the toilet from the self-cleaning toilet cleaner.

The present disclosure relates to an aerothermodynamic environment-friendly toilet, a mounting method, and an application of the aerothermodynamic environment-friendly toilet. The toilet includes a receiver, a processor, a solid storage device, a liquid storage device and a drying device. The toilet is odorless by using an aerothermodynamics principle. When no one uses the toilet, a fan at an exhaust port is used for exhausting a small amount of air from each cavity of the toilet to control an odor source unidirectionally; after use of the toilet, a waste treatment button is triggered, then hot air flow moves downwards, which downwards ejects air at an upper portion of a lower conical port of a reception guider of the receiver.