An electronic static weighing scale with a terminal, comprising an operator identification system and an operator-device interaction system, wherein the weighing terminal (2) has a housing situated horizontally on the measuring table, consisting of two elements, an upper housing part (3) and a lower housing part (4) arranged. The upper housing part (3) is located on the lower housing part (4) in such a way that their side parts are in contact with each other. The upper part of the housing (3) is equipped with a graphic display with a touch panel (5), which covers most of the surface of the upper part of the housing (3). The lower part of the terminal housing (4) has a raised elevation with a flat surface matching an integrated circuit surface on the weighing terminal's computer and these surfaces are in contact.

A weighing device includes: a weighing scale that measures a weight of a good; a communication interface that outputs goods purchase information including a purchase weight value based on a measured value by the weighing scale; and a central processing unit (CPU). In response to the CPU detecting that the measured value by the weighing scale has increased from zero to a positive value and then decreased from the positive value to zero, the communication interface outputs, as the purchase weight value, goods purchase information including the positive value.

Weighing scale apparatuses (devices and systems) and methods are implemented using a variety of biometric-based devices and methods. According to one such implementation, a weighing scale uses a base unit to integrate a support structure, a display, and circuitry to measure and determine the physiological parameters of the user, including a user-weight metric. The support structure includes a platform region that utilizes sensor circuitry to collect physiological data from the user, which is then processed by user-targeted circuitry to determine the physiological parameters (e.g., weight and heart-related measurements) of the user. Such parameters are then associated with the user and saved to a data-access circuit, and also forwarded to a display which communicates the physiological parameters among other information to the user through the platform region; the display encompassing substantially all of the platform region, including the region(s) upon which the user would stand for weight measurements.

An arrangement of connector ports for an electronic device, specifically for a weighing platform unit (1), includes a plurality of connector sockets (22, 23, 25, 26) which are installed in one or more walls of a chassis (4) thereof. The one or more walls that carry the connector sockets are interior partitioning walls that define a connector port compartment (20) inside the chassis. Furthermore, at least one wall section of the connector port compartment is an exterior wall section of the chassis and contains a passage opening (21). Electrical cables (30) that are terminated by plugs matching the connector sockets can be introduced into the connector port compartment through this passage opening.

A portable luggage scale including a housing assembly and a measuring assembly. The housing assembly includes a housing. The housing is removably attached to a suitcase or luggage. The housing has a lid hingedly attached thereto. The measuring assembly includes a weight measuring device and a light emitting diode (LED) display. The weight measuring device measures the weight inside the housing. The LED display is used to visualize the weight measured by the weight measuring device. The LED display and the weight measuring device are powered by a battery.

A Weighing scale which includes a platform, electronics housing and a rotating member. The platform includes a plurality of load cells. The electronic housing includes a processor coupled with the load cells for determining the weight of a load when the load is located on the platform. The rotating member rotatebly couples the platform with the electronics housing such that the electronic housing and the platform can rotate one with respect to the other.

Weighing scale apparatuses (devices and systems) and methods are implemented using a variety of biometric-based devices and methods. According to one such implementation, a weighing scale uses a base unit to integrate a support structure, a display, and circuitry to measure and determine the physiological parameters of the user, including a user-weight metric. The support structure includes a platform region that utilizes sensor circuitry to collect physiological data from the user, which is then processed by user-targeted circuitry to determine the physiological parameters (e.g., weight and heart-related measurements) of the user. Such parameters are then associated with the user and saved to a data-access circuit, and also forwarded to a display which communicates the physiological parameters among other information to the user through the platform region; the display encompassing substantially all of the platform region, including the region(s) upon which the user would stand for weight measurements.

A jack assembly includes a body. The jack assembly also includes a lifting piston positioned at least partially above the body and configured to move up and down with respect to the body. The jack assembly also includes a lock collar positioned at least partially around the lifting piston. The lock collar is configured to move up and down with respect to the lifting piston in response to rotating the lock collar with respect to the lifting piston. The jack assembly also includes a load cell positioned at least partially around the lifting piston and between the body and the lock collar. The jack assembly is configured to support an object, which exerts a downward force onto the lifting piston. The downward force is transferred from the lifting piston to the lock collar to the load cell to the body. The load cell measures the downward force.

A scale includes a weigh station for receiving items to be weighed, an operator interface configured to display information associated with scale operations, the operator interface comprising a touch-screen display, and a controller operably coupled to the operator interface to effect display of information thereon, the controller configured such that a home interface screen view is displayed on the operator interface. The home interface screen view includes one or more selectable regions that enable the operator to identify to the controller an item to be weighed. The home interface screen view includes no more than two pricing and labeling operation fields. In implementations, the controller is configured such that, upon operator identification of the item to be weighed via one of the one or more selectable regions, the controller effects display of an identified item screen interface view that includes at least five pricing and labeling operation fields.

A portable weighing system includes: a portable table; a battery disposed on the portable table and that includes an external charge port configured to receive power for charging the battery; a scale that is disposed on the portable table, that receives power from the battery by wire, and that measures weights of objects, respectively, placed on the scale; a user interface module disposed on the portable table and configured to receive the measured weights of the objects, respectively, from the scale by wire from the scale; and a cellular hotspot module disposed on the portable table and configured to: receive the measured weights of the objects, respectively, wirelessly from the user interface module; and transmit the measured weights of the objects, respectively, via a cellular network.