An agricultural vehicle including a container, which is mounted on at least one train of wheels, wherein the container rests by way of fixation brackets and load cells or weight sensors, preferably directly, i.e. without use of an intermediate chassis, on one axle or more forming the train of wheels. The vehicle container is mounted on the axle or each of the axles of the train under consideration by way of at least two pairs of load cells, wherein each pair consists of two load cells situated on opposite sides of a vertical plane parallel to the vertical planes containing the axes of the axles of a multi-axle train.

The invention relates to a load cell symmetrical about a central vertical axis and comprising first and second mounting surfaces, each on the same horizontal plane and configured for attachment to a support structure and to a loading fixture respectively.

The disclosed technology relates to systems and methods for weighing transportation vehicles and cargo and determining their load state. The disclosed technology can include a sensor controller configured to received one or more sensor readings from weight sensors on a cargo vehicle. The sensor controller can determine an inclination and/or deflection of the cargo vehicle and modify the sensor readings based on the inclination and/or deflection. The sensor controller can calculate a weight of cargo carried by the cargo vehicle based on the modified sensor readings.

In a weighing method, a weight (W) of a measured object (7) is measured. A roll angle (r) and a pitch angle (p) of a weighing scale platform (100) are read. The coordinates of a placement position (x.sub.0, z.sub.0) of the measured object are acquired. A first error (error1) caused by a weighing state according to the roll angle and the pitch angle is calculated. A second error (error2) caused by a weighing position according to the coordinates of the placement position, the roll angle (r) and the pitch angle (p) is also calculated. From these, a corrected weight (Wc) is determined.

An inclination of a weighing apparatus is automatically detected by the apparatus itself while preventing an increase in the number of components. In order to achieve the object described above, a weighing apparatus includes a weight sensor, a built-in weight to be loaded on the weight sensor, an adding/removing unit for adding/removing the built-in weight, a memory storing a theoretical value of the built-in weight, and an arithmetic processing unit, wherein the arithmetic processing unit includes an inclination angle computing unit configured to obtain an apparatus inclination angle from an arc-cosine of a weighing value of the built-in weight and the theoretical value of the built-in weight.

A weight scale system is for measuring the weight of an object, which includes a bed section, a vertical separator actuator and a controller. The bed section includes a lower-platform, an upper-platform and weight sensor assemblies located on the lower-platform, each includes at least one weight sensor. The bed section further includes at least one vertical-separator. The vertical-separator actuator is coupled with the vertical-separator and with the controller. The controller is coupled with the weight sensors. The controller directs the vertical-separator actuator to operate the bed section in at least two modes, a referencing mode in which the vertical-separator detaches the upper-platform from the weight sensor assemblies, thereby enabling referencing the weight sensors, and a weighing mode, in which the vertical separator re-attaches the upper-platform with the weight sensor assemblies, such that the weight associated with the upper-platform is fully applied on the weight sensors.

The invention relates to controlling a driving condition for an agricultural machine having a tractor, an implement for applying materials selected from the group of granular material, liquid material, and a powder-form material, the implement carried or trailed by the tractor and comprising a supply container, an application device, and a weight sensor device having at least one weight sensor and configured to sense an empty weight and a filling weight for the supply container. A tractor implement management system is provided and is operationally connected to the weight sensor device and configured for controlling driving conditions of the tractor. The method comprises driving the tractor, measuring first weight signals, indicative of a first driving condition, providing first tractor control signals, generated in response to the first weight signals and configured to apply a first control condition to the tractor driving, for controlling the tractor driving.

A Lift truck with a lifting device comprises at least one lifting member (1) provided with lifting means for adjusting the lifting member in height direction. The lifting member (1) comprises a shell part (50) lying over a base part (2) and having a surface on which cargo can be received. The shell part supports from a pressure point on the base part (2) via an electronic force sensor (10). The force sensor (10) is able and configured to determine vertical load on the shell part (50) and to generate an electronic signal as measure thereof, and comprises for this purpose pressure and/or strain-sensitive sensor means. In a longitudinal direction of the lifting member directed transversely of the vertical load there is provided between the sensor means and the pressure point a mechanical deformation zone (31,32,33) which is able and configured to deform in at least substantially wholly elastic manner, under the influence of a force effect exerted thereon in the longitudinal direction, from a rest state to a state deformed in the longitudinal direction.

A swivel foot assembly for a force plate or balance plate is disclosed herein. The swivel foot assembly includes a foot attachment component including a stem portion and a body portion, the stem portion of the foot attachment component configured to be attached to a force plate or balance plate; and a foot base component including a receptacle for receiving the body portion of the foot attachment component, the foot base component configured to be disposed on a support surface. The swivel foot assembly is configured to accommodate an uneven support surface on which a force plate or balance plate is disposed so that a force measurement accuracy of the force plate or balance plate is not adversely affected by stresses resulting from the uneven support surface.

Device for use as shopping and payment system for any kind of goods.