A force transmission element for a balance or load cell is adapted to be arranged between a load receiving unit, receiving the load to be weighed, and a load application point of a load cell, in order to transmit the load force exerted by the load. The force transmission element is designed at least partly as a framework composed of hollow rods, in particular round rods, wherein the force transmission element, in particular the hollow rods, is/are produced at least partly using 3D printing technology.

A fluid container measurement system is disclosed. The fluid container measurement system is configured to suspend a load measurement assembly a distance above a support surface. The load measurement assembly houses a load cell and a measurement control circuit. The measurement control circuit is coupled to the load cell and configured to receive electrical signals indicative of a force imposed on the load cell. Electrical signals generated by the load cell indicative of the force exerted on the load cell can be used to measure the fluid container attached to the load cell linkage member.

A fluid container measurement system is disclosed. The fluid container measurement system is configured to suspend a load measurement assembly a distance above a support surface. The load measurement assembly houses a load cell and a measurement control circuit. The measurement control circuit is coupled to the load cell and configured to receive electrical signals indicative of a force imposed on the load cell. Electrical signals generated by the load cell indicative of the force exerted on the load cell can be used to measure the fluid container attached to the load cell linkage member.

An apparatus includes a platform or other accessory that is supported by one or more piezoelectric transducers. As items are placed on or removed from the accessory, the piezoelectric transducer generates an electric charge that is representative of a change in weight. An amplifier receives the charge and provides output voltage that can be sampled to determine a weight value. In one implementation the platform may be supported by a transducer assembly comprising a frame and a pair of piezoelectric transducers on opposite sides of the frame. Signals from the pair may be used to compensate for environmental effects on the assembly, such as changes in temperature. The piezoelectric transducers and associated circuitry are extremely energy efficient, consuming little electrical power during operation.

An apparatus includes a platform or other accessory that is supported by one or more piezoelectric transducers. As items are placed on or removed from the accessory, the piezoelectric transducer generates an electric charge that is representative of a change in weight. An amplifier receives the charge and provides output voltage that can be sampled to determine a weight value. In one implementation the platform may be supported by a transducer assembly comprising a frame and a pair of piezoelectric transducers on opposite sides of the frame. Signals from the pair may be used to compensate for environmental effects on the assembly, such as changes in temperature. The piezoelectric transducers and associated circuitry are extremely energy efficient, consuming little electrical power during operation.

In order to ensure communication performance, a weight measuring device 1 includes a weight measurer configured to have a measurement target object placed thereon and measure a weight of the measurement target object, a communication module configured to transmit a measurement value of the weight of the measurement target object measured by the weight measurer by wireless communication, and an arrangement unit formed in an upper part of the weight measurer, the arrangement unit being configured to have at least an antenna of the communication module disposed on an upper side of the weight measurer.

A weighing system includes a support, a load cell mounted to the support, and a part platform suspended from the load cell to receive a part to be weighed. The load cell is operable to generate thousands of weight values for the part per second over a period of less than twenty seconds. The load cell is operable to output a weight of the part by averaging the weight values over the period of less than twenty seconds. A method of weighing the part suspended from the load cell is also disclosed.

A weighing system includes a support, a load cell mounted to the support, and a part platform suspended from the load cell to receive a part to be weighed. The load cell is operable to generate thousands of weight values for the part per second over a period of less than twenty seconds. The load cell is operable to output a weight of the part by averaging the weight values over the period of less than twenty seconds. A method of weighing the part suspended from the load cell is also disclosed.

The utility model discloses a carrier structure for multiple weight sensors, comprising bearing assemblies and a positioning device, wherein at least two bearing assemblies are provided; and the bearing assembly comprises a positioning end and a bearing branch end, the positioning end is fixedly connected with the bearing branch end, and a positioning hole is formed in one end face of the bearing branch end. According to the carrier structure for the multiple weight sensors, multiple weight sensor units in multiple directions can be combined, designed and mounted according to requirements, and quality detection information in multiple directions is obtained through the multiple weight sensing units, thus realizing multi-point and multi-position measurement; and the weight sensor units of multiple specifications can be designed and mounted at the same time, so that a corresponding sensing mode is effectively selected according to actual use conditions, thus improving measurement accuracy.

The utility model discloses a carrier structure for multiple weight sensors, comprising bearing assemblies and a positioning device, wherein at least two bearing assemblies are provided; and the bearing assembly comprises a positioning end and a bearing branch end, the positioning end is fixedly connected with the bearing branch end, and a positioning hole is formed in one end face of the bearing branch end. According to the carrier structure for the multiple weight sensors, multiple weight sensor units in multiple directions can be combined, designed and mounted according to requirements, and quality detection information in multiple directions is obtained through the multiple weight sensing units, thus realizing multi-point and multi-position measurement; and the weight sensor units of multiple specifications can be designed and mounted at the same time, so that a corresponding sensing mode is effectively selected according to actual use conditions, thus improving measurement accuracy.