A weighing apparatus is disclosed, the apparatus comprising: a container suitable for containing at least one object to be weighed; a supporting frame mechanically coupled to said container for relative movement therebetween and configured to freely support said container; a load cell operable to measure a force exerted on said supporting frame by said container; and a motor apparatus operable to exert a force on said load cell.

The invention discloses a solar electronic scale which comprises a casing without an external interface; a panel is covered with the casing, and together with the casing forms an accommodating cavity; a display assembly is installed in the accommodating cavity, and can display various information to the outside; the sensing component is arranged on the casing and can be in contact with the support platform; wherein the sensing component is used to sense the target weighing object placed on the panel to obtain the target weighing object and transmit the weight information to the display assembly for display; the power supply component includes the battery and the solar charging component, both of which are arranged in the accommodating cavity; the battery is electrically connected to the display assembly, the induction component and the solar charging component, and can balance power consumption for power consumption components in the accommodating cavity through the solar charging assembly. The solar electronic scale can meet the needs of users for weighing anytime and anywhere, and is conducive to ensuring the weighing accuracy of the electronic scale.

A device for dosing bulk material, in particular plastic granules, for machines that process plastic granules, in particular for injection moulding machines. The invention provides a bulk material feed (1), a material hopper (3) formed by multiple, preferably four, individually removable material hopper containers (2) and arranged under the bulk material feed (1) and ending in a dosing base device (4), and, optionally, a weighing container with a scale in the dosing base device (4). The individual material hopper containers (2) are arranged on a support spider (5) and the support spider (5) is formed by support spider plates (11) arranged vertically and perpendicular to one another. The support spider is mounted on the housing of the dosing base device (4). The support spider (5) has a height (h), which is at least the height (h.sub.1) of the material hopper container (2), which extends over the dosing base device (4), and corresponds to the immersion depth (h.sub.2) of the material hopper (3) into the dosing base device (4). A material hopper cover (6) is provided on the end of the support spider (5) facing away from the dosing base device (4).

A modular weighing device includes a basic base module and a plurality of extension modules mechanically and electrically connected to the basic base module in a disconnectable manner. Each extension module includes an add-on base module and a connection module. The extension modules are arranged adjacent to one another and are each mechanically and electrically connected to one another in a disconnectable manner to form a stack of extension modules and the basic base module is electrically and mechanically connected to one of the outer extension modules of the stack in a disconnectable manner. The connection modules can comprise electronic evaluation and/or control units for weighing components or can comprise weighing cells.

A modular weighing device includes a basic base module and a plurality of extension modules mechanically and electrically connected to the basic base module in a disconnectable manner. Each extension module includes an add-on base module and a connection module. The extension modules are arranged adjacent to one another and are each mechanically and electrically connected to one another in a disconnectable manner to form a stack of extension modules and the basic base module is electrically and mechanically connected to one of the outer extension modules of the stack in a disconnectable manner. The connection modules can comprise electronic evaluation and/or control units for weighing components or can comprise weighing cells.

A moving wing waterfowl or migratory bird decoy including a decoy body constructed of a predetermined material with exterior ornamentation to simulate a live waterfowl or migratory bird, the decoy body being arranged in a predetermined orientation to simulate a waterfowl or migratory bird, the decoy body having a top and a bottom. The decoy has at least one decoy wing connected to the decoy body, the decoy wing being constructed and arranged to simulate the wing of a waterfowl or migratory bird. The decoy body is constructed and arranged of a particular plastic material to hyper-realistically resemble a waterfowl or migratory bird. The control and power module is plug and play software controllable. The decoy is mountable on a male type member post via a female type receptacle on the decoy body. The decoy has a biased stabilizer cord that also mimics the legs of the waterfowl or migratory bird.

A shelf bracket assembly is mounted on a vertically disposed shelf upright, and has: at least one weighing device; an anchoring device; and a cantilever for supporting a shelf panel. In a condition where the shelf bracket assembly is mounted on the shelf upright, the cantilever projects from the shelf upright in a substantially horizontal direction. The cantilever has a vertically disposed metal plate. In a Cartesian coordinate system, an extent of the cantilever in a horizontal plane defines a Y-direction, a vertical direction defines a Z-direction, and a direction perpendicular to the Y-direction and the Z-direction defines an X-direction. The at least one weighing device includes: a force-introduction section; a linkage section; and a force-supporting section. The linkage section comprises two weighing plates extending horizontally and parallel to each other. The force-supporting section and the force-introduction section are at least partially formed of vertically extending metal plates.

A portable food scale includes: (a) a body portion having an upper body portion and a lower body portion, wherein a cavity is defined between the upper body portion and the lower body portion; (b) a plurality of load cells housed within the cavity; and (c) a plurality of clip portions securing the upper body portion to the lower body portion, each of the clip portions being engaged with at least one of the plurality of load cells.

A method includes receiving, via an electronic scale device supporting a user thereon, an indication to begin a verified weight sequence. Responsive to the indication to begin, the method includes: (1) determining a body weight of the user supported by the electronic scale device, (2) receiving, via an electronic device, image data that is reproducible as a visual image of at least a portion of the user supported on the housing of the scale, and (3) generating a data file including: (a) weight data that is representative of the determined body weight of the user supported by the housing, (b) the image data, and (c) time data corresponding to a date and time that the body weight of the user was determined.

A weighing scale is provided at a product processing workstation having a horizontal bed for supporting a horizontal bed window and an upright raised tower for supporting an upright tower window. A platter is mounted on the scale for joint movement therewith. The platter has a horizontal platter portion at least partly overlying the horizontal bed, and an upright platter portion at least partly overlying the raised tower. A guard on the upright platter portion overlies parts of the workstation for reducing weighing errors associated with weighing a product on the scale. The guard prevents the product from contacting and resting on the parts of the workstation and from being erroneously weighed.