A scale apparatus is described. The scale apparatus may include a housing sized to fit within a playing card tuck box; a pressure plate operable to measure a weight of a plurality of objects; a wireless transmitter; and a microcontroller in communication with the pressure plate and the wireless transmitter. The microcontroller may be configured to: continuously measure the weight on the pressure plate; when the weight holds steady for a sequence of measurements, transmit a first weight measurement via the wireless transmitter; measure a change in the weight; and when the change in the weight is steady, transmit a second weight measurement via the wireless transmitter.

Described herein is a weight or pressure measuring shovel. The shoveling apparatus has a broad blade assembly or scoop assembly including an elongate handle member. A coupler assembly is designed to couple the curved plate assembly to allow angular orientation or movement of the curved plate assembly to be adjusted relative to the handle member. A force transducer converts the weight or pressure of a material on the curved plate assembly into an electrical signal designed to communicate the weight or pressure of a material such as snow, sand, dirt, or ice. A control module in a housing mounted on the elongate handle is designed to receive electrical signals from the force transducer assembly or a load cell assembly. A display assembly is coupled to the electrical scale assembly and control module.

A system for signaling an overload of a foam mattress, including a foam mattress having a plurality of conductive inserts located near a bottom surface and a contact pad positioned below the bottom surface of the mattress. The system may generate an overload alarm signal as a function of receiving one or more signal outputs from the sensor over a period of time. The system may also generate an overload alarm signal as a function of receiving a plurality of individual signal outputs from a plurality of one or more conductive inserts located within a predetermined area of the sensor.

A proposing an improvement in an installation environment of a weighing apparatus is made by including (a) a step of acquiring, weighed data of an object (7) to be weighed from a weighing sensor (13) together with time information, (b) a step of acquiring, environmental data together with time information, (c) a step of checking, with respect to the weighed data and the environmental data, whether an amount of change of the data per unit time or an average value of the data is less than or not less than a threshold with reference to a threshold database (191) and determining influence on the apparatus, and (d) a step of making a proposal on the installation environment for each result of the determination with reference to an improvement proposal database (193).

A proposing an improvement in an installation environment of a weighing apparatus is made by including (a) a step of acquiring, weighed data of an object (7) to be weighed from a weighing sensor (13) together with time information, (b) a step of acquiring, environmental data together with time information, (c) a step of checking, with respect to the weighed data and the environmental data, whether an amount of change of the data per unit time or an average value of the data is less than or not less than a threshold with reference to a threshold database (191) and determining influence on the apparatus, and (d) a step of making a proposal on the installation environment for each result of the determination with reference to an improvement proposal database (193).

A weighing apparatus includes a load cell assembly with an elongated load cell body including a first three dimensional coordinate orientation defined by a first X-axis, a first Y-axis and a first Z-axis. An accelerometer unit is operatively connected to the elongated load cell body and having a second three-dimensional coordinate orientation defined by a second X-axis, a second Y-axis and a second Z-axis. A memory unit is mounted on the elongated load cell body, the memory unit storing data for aligning the second three-dimensional coordinate orientation of the accelerometer unit with the first three-dimensional coordinate orientation of the elongated load cell body.

The invention relates to a floor element (1) for installation in a floor of a building room, in particular a sanitary room, which is provided with a personal scale (3), preferably an electronic or electromechanical personal scale, or a measuring device for measuring a measured variable proportional to the weight force. The floor element (1) is preferably designed as a shower tray or shower floor element. Furthermore, the invention relates to a system comprising such a floor element (1) and a display device (10), wherein the display device (10) can be remotely and/or variably positioned relative to the floor element (1).

The invention relates to a floor element (1) for installation in a floor of a building room, in particular a sanitary room, which is provided with a personal scale (3), preferably an electronic or electromechanical personal scale, or a measuring device for measuring a measured variable proportional to the weight force. The floor element (1) is preferably designed as a shower tray or shower floor element. Furthermore, the invention relates to a system comprising such a floor element (1) and a display device (10), wherein the display device (10) can be remotely and/or variably positioned relative to the floor element (1).

Systems and methods for controlling a scale. One system includes a first touchless button, a first visual indicator associated with the first touchless button, a second touchless button, coupled to an electronic processor. The electronic processor is configured to receive, from the first touchless button, a first signal indicative of a first gesture. The electronic processor is configured to, in response to receiving the first signal, switch second touchless button from a dormant mode to an active mode and activate the first visual indicator. The electronic processor is configured to receive, from the second touchless button, a second signal indicative of a second gesture. The electronic processor is configured to, in response to receiving the second signal, execute a function of the scale associated with the second touchless button. The electronic processor is configured to switch the second touchless button from the active mode to the dormant mode.

Systems and methods for controlling a scale. One system includes a first touchless button, a first visual indicator associated with the first touchless button, a second touchless button, coupled to an electronic processor. The electronic processor is configured to receive, from the first touchless button, a first signal indicative of a first gesture. The electronic processor is configured to, in response to receiving the first signal, switch second touchless button from a dormant mode to an active mode and activate the first visual indicator. The electronic processor is configured to receive, from the second touchless button, a second signal indicative of a second gesture. The electronic processor is configured to, in response to receiving the second signal, execute a function of the scale associated with the second touchless button. The electronic processor is configured to switch the second touchless button from the active mode to the dormant mode.