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.

A recycling method includes the steps of compacting recyclable material into a fixed bale, and weighing the recyclable material, using load cells, independently of the compacting forces. Compacting equipment for performing the method includes balers with load cells and anchors, with the load cells weighing the baler and the recyclable material in the baler, and with the anchors anchoring the baler in place without interfering with the weighing.

A recycling method includes the steps of compacting recyclable material into a fixed bale, and weighing the recyclable material, using load cells, independently of the compacting forces. Compacting equipment for performing the method includes balers with load cells and anchors, with the load cells weighing the baler and the recyclable material in the baler, and with the anchors anchoring the baler in place without interfering with the weighing.

In a dynamic scale and a weighing method therefor, an object to be weighed is received on a weighing unit of the dynamic scale and weight information of the object on the weighing unit is detected by the weighing unit. The weight information includes a number of items of weight information, which are supplied to a processor, and a derived weight value is determined in the processor by evaluation of a predetermined number of the items of weight information, and a quality value for the derived weight value is also determined in the processor by evaluation of the predetermined number of items of weight information. Depending on the quality value, it is established, in the processor, that the derived weight value is a valid weight value and, when it is established that the derived weight value is a valid weight value, the weighing unit is then fed with a new object.

In a dynamic scale and a weighing method therefor, an object to be weighed is received on a weighing unit of the dynamic scale and weight information of the object on the weighing unit is detected by the weighing unit. The weight information includes a number of items of weight information, which are supplied to a processor, and a derived weight value is determined in the processor by evaluation of a predetermined number of the items of weight information, and a quality value for the derived weight value is also determined in the processor by evaluation of the predetermined number of items of weight information. Depending on the quality value, it is established, in the processor, that the derived weight value is a valid weight value and, when it is established that the derived weight value is a valid weight value, the weighing unit is then fed with a new object.

Methods of detecting scan avoidance events during decode sessions are disclosed herein. An example method includes during a timeout period at one or more processors of the symbology scanner, identifying and decoding a transaction affecting indicia on an object in one or more images to obtain a transaction affecting payload; during the timeout period at the one or more processors, identifying one or more visual features in the one or more images; and in response to identifying a non-transaction affecting indicia associated with the one or more visual features, and failing to identify or decode the transaction affecting indicia, determining a potential scan avoidance attempt and generating a scan avoidance alarm signal.

An example product identification and weighing apparatus for use with a POS terminal includes a weigh platter; a scale configured to measure a weight of the item when placed on the weigh platter; an off-platter detection assembly configured to detect an off-platter condition; a product identification assembly configured to identify the item; a communication interface configured to communicate with the POS terminal; a processor in communication with the scale, the off-platter detection assembly, and the communication interface; and a non-transitory machine-readable storage medium storing instructions that, when executed by the processor, cause the object recognition and weighing apparatus to, responsive to detecting the off-platter condition, prevent a transmission of the identified item to the POS terminal until the off-platter condition is no longer detected.

An example product identification and weighing apparatus for use with a POS terminal includes a weigh platter; a scale configured to measure a weight of the item when placed on the weigh platter; an off-platter detection assembly configured to detect an off-platter condition; a product identification assembly configured to identify the item; a communication interface configured to communicate with the POS terminal; a processor in communication with the scale, the off-platter detection assembly, and the communication interface; and a non-transitory machine-readable storage medium storing instructions that, when executed by the processor, cause the object recognition and weighing apparatus to, responsive to detecting the off-platter condition, prevent a transmission of the identified item to the POS terminal until the off-platter condition is no longer detected.

A weighing device is disclosed including a motor that can be used to rotate a drive head. The drive head supports a cylindrical spindle having a plurality of holes or recesses. The spindle is configured so that it can be easily removed from the rotatable drive head and placed on a load sensor that can be used for weighing the device. In use a blister strip (not shown) can be loaded onto the spindle. An evacuation unit is provided with a pair of cutting blades. The load sensor can determine a first measurement of weight when the blisters are full of powder and a second measurement of weight after the evacuation unit has been used to evacuate receptacles supported on the spindle.

A weighing device is disclosed including a motor that can be used to rotate a drive head. The drive head supports a cylindrical spindle having a plurality of holes or recesses. The spindle is configured so that it can be easily removed from the rotatable drive head and placed on a load sensor that can be used for weighing the device. In use a blister strip (not shown) can be loaded onto the spindle. An evacuation unit is provided with a pair of cutting blades. The load sensor can determine a first measurement of weight when the blisters are full of powder and a second measurement of weight after the evacuation unit has been used to evacuate receptacles supported on the spindle.