A sensor assembly for equipment for aiding the traceability of agri-food products includes: a casing having a first face, configured to be coupled to a planar structure, and a second face; a weighing device responding to a load on the second face of the casing, an inclinometer, and an accelerometer configured to supply an acceleration signal indicative of accelerations along an axis perpendicular to the first face of the container. A processing unit detects a measured weight bearing on the weighing device based on load signals supplied by the weighing device, on an inclination signal supplied by the inclinometer and on the acceleration signal supplied by the accelerometer.

A sensor assembly for equipment for aiding the traceability of agri-food products includes: a casing having a first face, configured to be coupled to a planar structure, and a second face; a weighing device responding to a load on the second face of the casing, an inclinometer, and an accelerometer configured to supply an acceleration signal indicative of accelerations along an axis perpendicular to the first face of the container. A processing unit detects a measured weight bearing on the weighing device based on load signals supplied by the weighing device, on an inclination signal supplied by the inclinometer and on the acceleration signal supplied by the accelerometer.

A dynamic weighing device has a plurality of weighing sensors that constitute a weighing sensor network via Ethernet. One of the weighing sensors is selected as a primary node, which performs time synchronization with the other nodes via a time synchronization protocol. Alternatively, the other nodes synchronize a time offset relative to the time of the primary node. Each weighing sensor continuously packetizes and sends a plurality of consecutive pieces of weighing information to a terminal apparatus. The terminal apparatus calculates a weighed weight result of the dynamic weighing device at the same moment, based on time information in the weighing information obtained through depacketization, In such a weighing sensor network, by means of the time synchronization, weighing data at each moment is accurate when the weighing data is processed on a terminal such as a meter, thereby improving the reliability of sampling.

The present invention discloses a weighing and measuring system, comprising a weighing sensor network constituted by networking a plurality of weighing sensors, wherein in the weighing sensor network, each of subtasks into which a weighing task is split is assigned to each of weighing sensors in the weighing sensor network; and each of the weighing sensors respectively and independently executes the assigned subtask and exchanges task data through the weighing sensor network. The weighing sensors collaboratively process a weighing task, which no longer depends on an instrument or a computer, thereby reducing the cost of the whole system, and improving the tolerance level to environment. The collaborative processing mode also avoids the bottleneck of data communication information summarization.

Load cell lift-off protection devices with the load to be measured applied directly to the spherical upper surface of the load cell and with locking members which are locking grooves in the load cell force introducing parts to grooves in the structure of the weighed installation.

A dynamic weighing device has a plurality of weighing sensors that constitute a weighing sensor network via Ethernet. One of the weighing sensors is selected as a primary node, which performs time synchronization with the other nodes via a time synchronization protocol. Alternatively, the other nodes synchronize a time offset relative to the time of the primary node. Each weighing sensor continuously packetizes and sends a plurality of consecutive pieces of weighing information to a terminal apparatus. The terminal apparatus calculates a weighed weight result of the dynamic weighing device at the same moment, based on time information in the weighing information obtained through depacketization, In such a weighing sensor network, by means of the time synchronization, weighing data at each moment is accurate when the weighing data is processed on a terminal such as a meter, thereby improving the reliability of sampling.

A remaining mobile phase scale includes a weighing scale (2) including a plurality of individual stages (10A, 10B) on which mobile phase bottles containing a mobile phase are placed and a plurality of individual weight sensors (12A, 12B) that respectively measure weight of mobile phase bottles respectively placed on the plurality of individual stages (10A, 10B), a detachment-attachment holder (4) detachably and attachably placed on the plurality of individual stages (10A, 10B) such that the plurality of individual stages (10A, 10B) are integrated as one common stage, and a mobile phase monitor (6) that monitors a remaining amount of a mobile phase in mobile phase bottles, and the mobile phase monitor (6) is provided with a mode switcher (28) configured to selectively switch a mobile phase monitor mode to one of a normal mode and a large capacity mode.

A remaining mobile phase scale includes a weighing scale (2) including a plurality of individual stages (10A, 10B) on which mobile phase bottles containing a mobile phase are placed and a plurality of individual weight sensors (12A, 12B) that respectively measure weight of mobile phase bottles respectively placed on the plurality of individual stages (10A, 10B), a detachment-attachment holder (4) detachably and attachably placed on the plurality of individual stages (10A, 10B) such that the plurality of individual stages (10A, 10B) are integrated as one common stage, and a mobile phase monitor (6) that monitors a remaining amount of a mobile phase in mobile phase bottles, and the mobile phase monitor (6) is provided with a mode switcher (28) configured to selectively switch a mobile phase monitor mode to one of a normal mode and a large capacity mode.

A system is described including a scale device for measuring weight of a food container, wherein one or more applications run on at least one processor of the scale device and are configured to detect weight of the food container and its contents using the scale device. The one of more applications are configured to detect a first weight measurement of the food container, wherein the first weight measurement includes weight of the food container and a first amount of food, to detect a second weight measurement of the food container, wherein the second weight measurement includes the weight of the food container, the first amount of food, and a second amount of food, wherein the second weight measurement is an updated weight measurement of the food container, to subsequently log weight measurements of the food container at time intervals, and to intermittently adjust and monitor the updated weight measurement.

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.