Abstract: An apparatus for measuring the dimensions or volume of an object on a conveyor is disclosed. A light source on one side of the conveyor is focused onto a spinning scanning drum having a pattern of holes therethrough. The holes are arrayed in a spiral pattern. The rotating drum is positioned parallel to the dimension to be measured between the source of light and a light detector on the other side of the conveyor from the light source. The pattern of holes is arranged so that when the scanning drum rotates a scanning pattern is generated across the conveyor. The light detector on the other side of the conveyor generates an output signal each time a beam of light passes through the rotating scanning drum and across the conveyor. A controller receives the output signal and correlates the output signal with the scanning pattern using a look-up table. Using this information, the controller determines from the scanning pattern and the detected output signals, the dimension of the object.

Abstract: A modular checkweigher/grader system is disclosed. A feed conveyor is provided for directing items to be weighed to a weighing conveyor. The entire system is modularly designed using lightweight durable materials, such as plastics and stainless steel. Each conveyor includes a conveyor belt in contact with upper and lower surfaces of a platform. The belts are tightened and loosened with quick release tension clamps and driven by air powered motors. The feed conveyor is attached to a frame by toggle clamps. The weighing conveyor is attached to a load cell which is connected to the frame by toggle clamps. These toggle clamps permit the entire feed and weighing conveyors to be easily removed. All of the air and electrical connector to the conveyors are by quick release connectors. The entire weighing conveyor is used as the weighing platform. A tachometer may be used to regulate the conveyor speed. A modular grading conveyor is disclosed for categorizing objects from the weighing conveyor.

Abstract: A microprocessor (8) controlled power-saving electronic measuring system is disclosed. A load cell (1) generates an output signal indicative of the magnitude of the load applied to the cell (1). A DC power supply (2) is switched to supply the load cell (1) with power pulses (10) at varying frequencies and duty cycles determinable by the microprocessor (8) to optimize battery life. The microprocessor (8) determines the optimal duty cycle and frequency for the power pulses responsive to desired parameters. The circuitry of the present invention is located in close proximity to a temperature sensor (34) which accurately reads the temperatures of all of the components and compensates for all heat related inaccuracies simultaneously. The microprocessor (8) determines a temperature corrected value for the load cell (1) output via a previously programmed table containing the temperature response characteristics for the load cell (1) and the circuitry.

Abstract: An electronic weighing system is disclosed which, employs spaced cylindrical dielectric rings as the load measuring transducer. A support structure is provided to linearly vary the spacing between the rings responsive to applied load which will linearly vary the resonant frequency of the rings. In an active mode, each microwave load cell is excited by an unstable oscillator, the dielectric rings stabilizing the oscillator at a resonant frequency which is proportional to their spacing. The oscillation frequency of the load cell is measured and used to compute the magnitude of the load applied to the cell based upon a predetermined relationship between output frequency and load. A plurality of multiplexed load cells may be employed. In a passive mode, a voltage controlled oscillator generates a microwave signal which linearly sweeps a preset frequency band. The sweeping signal is applied across the dielectric rings which generate a detectable pulse at their primary resonant frequency.

Abstract: A load indicator conversion system is disclosed for converting a scale having a mechanical measuring system, such as a conventional portable beam scale, into a scale having an electronic measuring system for providing an electronic display, such as an LCD display, corresponding to the load applied to the mechanical load receiver of the scale, such as the scale platform [104], which is mechanically linked via the beam load rod assembly [110] and an s-hook arrangement [150] to a load cell transducer [1]. A single common temperature sensor is employed adjacent the load cell and the associated electronics to provide information on the variations in temperature to the microprocessor for enabling temperature compensation to take place.

Abstract: A postal type scale (20), such as an electronic scale, capable of weighing a plurality of different size packages (24, 34) comprises a weighing mechanism (26), a platform (22) for supporting a package (24, 34) thereon in a weighing relationship, and a movable weight display (30, 36) slidably mounted to the platform (22) and longitudinally extendable therefrom along a horizontal mounting surface (38) when the platform (22) is supported on the horizontal mounting surface (38). The weight display (30, 36) comprises a horizontal weight display (30, 30b), such as an LCD display (30b), which may be removably mounted to the horizontally movable display mounting member (36) for providing the display (30) at a position remote from the mounting member (36).

Abstract: The portable deck truck scale includes a deck structure which has a plurality of "V"-shaped support ribs extending between a bottom plate and an upper deck. The support ribs are configured to provide increased strength at the side portions of the deck structure, and the upper deck is either a metal plate or a concrete slab. If a metal plate forms the upper deck, the central portion is reinforced by spaced strips positioned over the side portions of the deck. When the deck is concrete, it has a thickness within the range of from 2 to 4 inches. This is achieved by adding silica fume and steel fibers to the concrete mix. The deck structure is supported on a load cell beam having a flat upper surface which supports the flat surface of a load button. An opposed radiused surface of the load button supports the flat end surface of a rocker pin which engages the deck structure.

Abstract: The portable deck truck scale includes a deck structure which has a plurality of "V"-shaped support ribs extending between a bottom plate and an upper deck. The support ribs are configured to provide increased strength at the side portions of the deck structure, and the upper deck is either a metal plate or a concrete slab. If a metal plate forms the upper deck, the central portion is reinforced by spaced strips positioned over the side portions of the deck. When the deck is concrete, it has a thickness within the range of from 2 to 4 inches. This is achieved by adding silica fume and steel fibers to the concrete mix. The deck structure is supported on a load cell beam having a flat upper surface which supports the flat surface of a load button. An opposed radiused surface of the load button supports the flat end surface of a rocker pin which engages the deck structure.