A self-weighing container for transporting delivery items includes a weight-sensing device that is configured to sense a weight of a delivery item that is placed inside the container; a microcontroller that is connected to the weight-sensing device; and a display that is connected to the microcontroller. When a delivery item is placed in the container, the weight-sensing device produces a signal that corresponds to the weight of the delivery item and the microcontroller receives the signal and determines the weight of the delivery item based on the signal. The microcontroller may transmit an indication of the weight to the display, which displays the weight based on the indication of the weight, or the microcontroller may transmit the weight to a smart phone for display.

The invention relates to a kitchen scale comprising a carrying plate (1), a substructure (2) supporting the carrying plate, weighing cells (6) comprising at least one strain gauge (10), an electronics unit (4), which is capable of computing the weight of the load, and comprising a display device for displaying the ascertained weight and a battery compartment for accommodating a voltage source which supplies the electronics unit (4) with power. The weighing cell (6) has at least one strain gauge, which is at least partially provided with a parylene coating.

A telescoping weigh fork unit where a base fork has an integrated hydraulic cylinder and a slideable outer shoe on which are supported at least two load cells. Optionally the unit may include an outside telescopic fork shoe to which the load cells are mounted and which supports the outer shoe. Unit may further include a system to alert if distance or weight thresholds are exceeded or if a load cell is inoperable.

A telescoping weigh fork unit where a base fork has an integrated hydraulic cylinder and a slideable outer shoe on which are supported at least two load cells. Optionally the unit may include an outside telescopic fork shoe to which the load cells are mounted and which supports the outer shoe. Unit may further include a system to alert if distance or weight thresholds are exceeded or if a load cell is inoperable.

Systems and methods for controlling a scale. One system includes a first touchless button, a first visual indicator associated with the first touchless button, a second touchless button, coupled to an electronic processor. The electronic processor is configured to receive, from the first touchless button, a first signal indicative of a first gesture. The electronic processor is configured to, in response to receiving the first signal, switch second touchless button from a dormant mode to an active mode and activate the first visual indicator. The electronic processor is configured to receive, from the second touchless button, a second signal indicative of a second gesture. The electronic processor is configured to, in response to receiving the second signal, execute a function of the scale associated with the second touchless button. The electronic processor is configured to switch the second touchless button from the active mode to the dormant mode.

Systems and methods for controlling a scale. One system includes a first touchless button, a first visual indicator associated with the first touchless button, a second touchless button, coupled to an electronic processor. The electronic processor is configured to receive, from the first touchless button, a first signal indicative of a first gesture. The electronic processor is configured to, in response to receiving the first signal, switch second touchless button from a dormant mode to an active mode and activate the first visual indicator. The electronic processor is configured to receive, from the second touchless button, a second signal indicative of a second gesture. The electronic processor is configured to, in response to receiving the second signal, execute a function of the scale associated with the second touchless button. The electronic processor is configured to switch the second touchless button from the active mode to the dormant mode.

Conveyor idler monitoring apparatus, systems and methods are provided. In some embodiments, one or more sensors (e.g., temperature sensors, load sensors, etc.) are supported by the shaft of a conveyor idler. In some embodiments, one or more sensors are in data communication with a wireless transmitter. In some embodiments, a power generator driven by rotation of the idler is in electrical communication with one or more sensors and/or a wireless transmitter. In some embodiments, a plurality of idlers monitoring systems are in data communication with a conveyor monitoring system and/or operational monitoring system.

Conveyor idler monitoring apparatus, systems and methods are provided. In some embodiments, one or more sensors (e.g., temperature sensors, load sensors, etc.) are supported by the shaft of a conveyor idler. In some embodiments, one or more sensors are in data communication with a wireless transmitter. In some embodiments, a power generator driven by rotation of the idler is in electrical communication with one or more sensors and/or a wireless transmitter. In some embodiments, a plurality of idlers monitoring systems are in data communication with a conveyor monitoring system and/or operational monitoring system.

A self-weighing container for transporting delivery items includes a weight-sensing device that is configured to sense a weight of a delivery item that is placed inside the container; a microcontroller that is connected to the weight-sensing device; and a display that is connected to the microcontroller. When a delivery item is placed in the container, the weight-sensing device produces a signal that corresponds to the weight of the delivery item and the microcontroller receives the signal and determines the weight of the delivery item based on the signal. The microcontroller may transmit an indication of the weight to the display, which displays the weight based on the indication of the weight, or the microcontroller may transmit the weight to a smart phone for display.

A self-weighing container for transporting delivery items includes a weight-sensing device that is configured to sense a weight of a delivery item that is placed inside the container; a microcontroller that is connected to the weight-sensing device; and a display that is connected to the microcontroller. When a delivery item is placed in the container, the weight-sensing device produces a signal that corresponds to the weight of the delivery item and the microcontroller receives the signal and determines the weight of the delivery item based on the signal. The microcontroller may transmit an indication of the weight to the display, which displays the weight based on the indication of the weight, or the microcontroller may transmit the weight to a smart phone for display.