An object measurement device for ascertaining measurements of cuboidal and boxed packages to provide measurement data to a host computer is provided. The device may include a frame, a weight sensor, and one or more dimension sensors. The frame may include a base and a vertical support member that extends vertically from the base. The weight sensor may be positioned on the base and may be configured to emit a weight data signal. The dimension sensors may include an upper sensor and one or more side sensors. The upper sensor may be positioned on the vertical support member, and the side sensors may be positioned adjacent to the base. The dimension sensors may be configured to emit dimensional data signals. The host computer may be in communication with the weight and dimension sensors. The host computer may be configured to receive the weight and the dimensional measurement data.

A truck scale assembly comprised of a payload containment portion affixed to a frame, an array of load cell assemblies, and a display screen positioned on a pickup truck surface. The array features load cell assemblies arranged in spaced apart relationship along an underside of the payload containment portion to allow load information from various regions of the containment portion to be communicated to and visually displayed by the display screen, allowing a truck operator to understand payload weight and relative distribution in the payload containment portion of the pickup truck. One embodiment of the assembly is an aftermarket drop in liner installed in an existing truck bed assembly, and a second embodiment is factory installed, with the array sandwiched between an underside of the truck bed and the truck frame. Information from the array is transmitted by wired connection or wirelessly to the display screen.

A truck scale assembly comprised of a payload containment portion affixed to a frame, an array of load cell assemblies, and a display screen positioned on a pickup truck surface. The array features load cell assemblies arranged in spaced apart relationship along an underside of the payload containment portion to allow load information from various regions of the containment portion to be communicated to and visually displayed by the display screen, allowing a truck operator to understand payload weight and relative distribution in the payload containment portion of the pickup truck. One embodiment of the assembly is an aftermarket drop in liner installed in an existing truck bed assembly, and a second embodiment is factory installed, with the array sandwiched between an underside of the truck bed and the truck frame. Information from the array is transmitted by wired connection or wirelessly to the display screen.

A method for controlling an electronic scale in disclosed in this disclosure, which is applied to measure and indicate a state of an external force, comprises the following steps. A weight sensor detects the external force, and a controller drives a prompting device to emit a first light with a first optical characteristic when the external force detected by the weight sensor reaches a first weight. The controller drives the prompting device to emit a second light with a second optical characteristic when the prompting device emits the first light for a predetermined period, wherein the prompting device continuously emits the second light until the external force reaches a second weight.

Sensor stations and related systems and methods to monitor and measure properties of food products in food processing structures such as cure rooms, smokehouses, ovens, and related structures. The sensor stations allow real-time, local collection of product properties and their surrounding environmental conditions in order to improve efficiency, reduce product waste and guesswork, and to provide data-based analysis for decision making. Sensor stations can be mounted to food supports and can be in electronic communication with each other and with intermediate nodes that provide a connection to other external computing devices that provide analysis and alerts to users and technicians. Various non-destructive modeling systems for determining water activity and pH of changing products are also provided.

Sensor stations and related systems and methods to monitor and measure properties of food products in food processing structures such as cure rooms, smokehouses, ovens, and related structures. The sensor stations allow real-time, local collection of product properties and their surrounding environmental conditions in order to improve efficiency, reduce product waste and guesswork, and to provide data-based analysis for decision making. Sensor stations can be mounted to food supports and can be in electronic communication with each other and with intermediate nodes that provide a connection to other external computing devices that provide analysis and alerts to users and technicians. Various non-destructive modeling systems for determining water activity and pH of changing products are also provided.

A method for controlling an electronic scale in disclosed in this disclosure, which is applied to measure and indicate a state of an external force, comprises the following steps. A weight sensor detects the external force, and a controller drives a prompting device to emit a first light with a first optical characteristic when the external force detected by the weight sensor reaches a first weight. The controller drives the prompting device to emit a second light with a second optical characteristic when the prompting device emits the first light for a predetermined period, wherein the prompting device continuously emits the second light until the external force reaches a second weight.

A fluid container measurement system employing a load cell linkage member is disclosed. The fluid container measurement system is configured to suspend a load measurement assembly a distance above a support surface. The load measurement assembly houses a load cell and a measurement control circuit. The measurement control circuit is coupled to the load cell and configured to receive electrical signals indicative of a force imposed on the load cell. The load measurement assembly also includes or is configured to receive a load cell linkage member mechanically linked to the load cell. In this manner, a load placed on the load cell linkage member will be exerted on the load cell. Electrical signals generated by the load cell indicative of the force exerted on the load cell can be used to measure the fluid container attached to the load cell linkage member.

A fluid container measurement system employing a load cell linkage member is disclosed. The fluid container measurement system is configured to suspend a load measurement assembly a distance above a support surface. The load measurement assembly houses a load cell and a measurement control circuit. The measurement control circuit is coupled to the load cell and configured to receive electrical signals indicative of a force imposed on the load cell. The load measurement assembly also includes or is configured to receive a load cell linkage member mechanically linked to the load cell. In this manner, a load placed on the load cell linkage member will be exerted on the load cell. Electrical signals generated by the load cell indicative of the force exerted on the load cell can be used to measure the fluid container attached to the load cell linkage member.

A vehicle is provided that includes a body defining a roof. A roof rack is operably coupled to the roof through a plurality of mounting features and configured to support cargo. A load cell is positioned on each of the mounting features and configured to sense a load on the roof rack associated with the cargo. A controller is in communication with the load cells and an electronic device and a light source is positioned proximate each of the mounting features. The light source is configured to emit light based on the load sensed by the load cell.