Weighing and filling apparatus for controlling filling device based on a container weight. A linear actuator for driving a drive shaft coupled to container support unit is included, a weight measuring unit determines the container weight from a detected height of the drive shaft detected by a height detecting unit and a drive signal of the linear actuator at the detected height. A first acceleration signal is calculated from a specified height of the container support unit set in advance and the height detected by the height detecting unit, a second acceleration signal is calculated from the container weight and an expected weight expected to be applied to the container support unit. The container support unit is kept at the specified height by a drive signal calculated from the first and second acceleration signals.

Weighing and filling apparatus for controlling filling device based on a container weight. A linear actuator for driving a drive shaft coupled to container support unit is included, a weight measuring unit determines the container weight from a detected height of the drive shaft detected by a height detecting unit and a drive signal of the linear actuator at the detected height. A first acceleration signal is calculated from a specified height of the container support unit set in advance and the height detected by the height detecting unit, a second acceleration signal is calculated from the container weight and an expected weight expected to be applied to the container support unit. The container support unit is kept at the specified height by a drive signal calculated from the first and second acceleration signals.

An integrated high-precision weighing module has a shell, an electromagnetic force sensor, a printed circuit board (PCB), a weighing pan component, a support ring, and an air baffle ring. The electromagnetic force sensor and the PCB are mounted in the shell. A bearing head of the electromagnetic force sensor extends upward from an upper end portion of the shell. The support ring sheathes the bearing head. The weighing pan component is mounted on the bearing head, with the support ring located between the weighing pan component and the shell. The air baffle ring is disposed around the weighing pan component and located on the support ring. A first airflow channel is formed among the shell, the support ring, and the air baffle ring. At least part of airflow in the shell flows to the outside through the first airflow channel.

An integrated high-precision weighing module has a shell, an electromagnetic force sensor, a printed circuit board (PCB), a weighing pan component, a support ring, and an air baffle ring. The electromagnetic force sensor and the PCB are mounted in the shell. A bearing head of the electromagnetic force sensor extends upward from an upper end portion of the shell. The support ring sheathes the bearing head. The weighing pan component is mounted on the bearing head, with the support ring located between the weighing pan component and the shell. The air baffle ring is disposed around the weighing pan component and located on the support ring. A first airflow channel is formed among the shell, the support ring, and the air baffle ring. At least part of airflow in the shell flows to the outside through the first airflow channel.

A weight measurement device comprises: an upper surface cover on which a measurement target is placed; a load cell to detect weight of the measurement target placed on the upper surface cover; a bridge to support the load cell; a receiving member to receive the weight of the measurement target placed on the upper surface cover; and a bottom surface cover provided on a lower surface side of the receiving member, and further comprises a sliding part provided between the lower surface of the receiving member and an upper surface of the bottom surface cover to enable the receiving member to move in a horizontal direction relative to the bottom cover. The bridge comprises a pivot which is a fulcrum to make it possible to change inclination of the bridge relative to the bottom surface cover and is in contact with an upper surface of the receiving member.

A weight measurement device comprises: an upper surface cover on which a measurement target is placed; a load cell to detect weight of the measurement target placed on the upper surface cover; a bridge to support the load cell; a receiving member to receive the weight of the measurement target placed on the upper surface cover; and a bottom surface cover provided on a lower surface side of the receiving member, and further comprises a sliding part provided between the lower surface of the receiving member and an upper surface of the bottom surface cover to enable the receiving member to move in a horizontal direction relative to the bottom cover. The bridge comprises a pivot which is a fulcrum to make it possible to change inclination of the bridge relative to the bottom surface cover and is in contact with an upper surface of the receiving member.

A movable and modular device (100) for dynamic weighing of animals includes an identifying module (1) and a weighing module (2). The identifying module (1) includes a supporting structure (11), a processing module (12), a solar panel (13), an antenna (14), and an identifier (15); and a weighing module (2) comprising: a base (20), at least one pair of sidewalls (21), at least one weighing platform (22), at least one load cell (23), and at least one amplifier and transmission box (24). The device (100) is capable of providing the precise weight of each animal passing over the scale, wherein weighing can occur both when the animal stops on the scale and when it moves on the scale, and especially having movable characteristics, without the need for the animals to move from one area to another through a passageway formed between these two areas.

A movable and modular device (100) for dynamic weighing of animals includes an identifying module (1) and a weighing module (2). The identifying module (1) includes a supporting structure (11), a processing module (12), a solar panel (13), an antenna (14), and an identifier (15); and a weighing module (2) comprising: a base (20), at least one pair of sidewalls (21), at least one weighing platform (22), at least one load cell (23), and at least one amplifier and transmission box (24). The device (100) is capable of providing the precise weight of each animal passing over the scale, wherein weighing can occur both when the animal stops on the scale and when it moves on the scale, and especially having movable characteristics, without the need for the animals to move from one area to another through a passageway formed between these two areas.

A re-usable sensor module for use with a dispenser for a hand hygiene product is described, wherein the dispenser comprises a container. The sensor module comprises an elastically deformable capsule with a top portion for placing a bottom of the container thereon. A sensor is arranged within the capsule and configured to measure a parameter associated with an elastic deformation of the capsule resulting from actuation or presence of the dispenser. The sensor module further comprises a processor arranged within the capsule and coupled to the sensor. The processor is configured to at least temporarily record at least one of the parameter and an event associated therewith.

A re-usable sensor module for use with a dispenser for a hand hygiene product is described, wherein the dispenser comprises a container. The sensor module comprises an elastically deformable capsule with a top portion for placing a bottom of the container thereon. A sensor is arranged within the capsule and configured to measure a parameter associated with an elastic deformation of the capsule resulting from actuation or presence of the dispenser. The sensor module further comprises a processor arranged within the capsule and coupled to the sensor. The processor is configured to at least temporarily record at least one of the parameter and an event associated therewith.