A machine for conveying objects, including: a base; a turret mounted to the base for rotation about an axis, the turret including a turret mounted track, and a turret shuttle with a gripper to grip an object, the turret shuttle mounted on the turret mounted track; a boom mounted to the turret, whereby turret rotation sweeps the boom radially about the axis, the boom including: a boom mounted track extending therealong, a boom shuttle with a gripper to grip an object, the boom shuttle mounted to the boom mounted track, and a carousel located proximal to the base extending around the turret and rotatable about the axis, the carousel having a plurality of object bays, the carousel being controllably rotatable about the axis to locate any of the object bays proximal to the turret mounted track for transfer of an object between the object bay and the turret shuttle.

A computing device receives a setup command and signals mobile robots to move sensor targets into positions within a predetermined range of a turntable. Each mobile robot may be coupled to a sensor target. Once the sensor targets are moved into the positions, calibration may be initiated, in which a vehicle is rotated using the turntable, and sensors coupled to the vehicle are calibrated based on detection of the sensor targets. The computing device may signal the mobile robots to adjust the sensor targets as needed, or, after calibration, to move into storage or charging positions.

A computing device receives a setup command and signals mobile robots to move sensor targets into positions within a predetermined range of a turntable. Each mobile robot may be coupled to a sensor target. Once the sensor targets are moved into the positions, calibration may be initiated, in which a vehicle is rotated using the turntable, and sensors coupled to the vehicle are calibrated based on detection of the sensor targets. The computing device may signal the mobile robots to adjust the sensor targets as needed, or, after calibration, to move into storage or charging positions.

Quick service restaurants with car wash systems and traffic management systems for managing customer traffic and routing customers who have made food-only purchases and customers who have purchased both a food item and a carwash service. In some examples, graphical user interfaces incorporated in point of sale systems display time predictions for the delivery of food items and carwash services to aid and encourage customer selection of both food items and carwash services.

Quick service restaurants with car wash systems and traffic management systems for managing customer traffic and routing customers who have made food-only purchases and customers who have purchased both a food item and a carwash service. In some examples, graphical user interfaces incorporated in point of sale systems display time predictions for the delivery of food items and carwash services to aid and encourage customer selection of both food items and carwash services.

A transporting system and method for a linear motor conveyor system, wherein the conveyor system includes at least one moving element and at least one track on which the moving element moves, the transporting system including: a rotatable element; a motor for rotating the rotatable element; a coupler connected to the rotatable element, wherein the coupler is configured to engage with the moving element when the coupler is positioned in a predetermined relationship with the moving element; and a controller configured to: operatively connect with the linear motor conveyor system; and control at least one of the moving element and the rotatable element so that the coupler is positioned in the predetermined relationship with the moving element on the track such that the coupler strips the moving element off the track.

A method of accumulating packages and an accumulation module including a base cabinet, a rotatable accumulation dial, a hopper and picker assembly, the picker assembly extendable radially outward from a home position to a position outside of the hopper to retrieve a package and place the package on the accumulation module. The package is acted on by a first plunger from above and a stabilizing plunger from below to hold the package in place and then the package is treated by a heat stake anvil from below.

A method of accumulating packages and an accumulation module including a base cabinet, a rotatable accumulation dial, a hopper and picker assembly, the picker assembly extendable radially outward from a home position to a position outside of the hopper to retrieve a package and place the package on the accumulation module. The package is acted on by a first plunger from above and a stabilizing plunger from below to hold the package in place and then the package is treated by a heat stake anvil from below.

The present disclosure relates to a system and a method for fine manipulation. The system for fine manipulation includes a tossing mechanism, a setting mechanism, and a leaf uniformly distributing mechanism. The tossing mechanism comprises a tossing machine, a leaf distributing assembly, a first feeding conveyor assembly, and a first receiving conveyor assembly. The setting mechanism comprises a setting assembly, a second feeding conveyor assembly, and a second receiving conveyor assembly. The setting assembly includes a setting belt and a setting belt driving device configured to drive the setting belt to move. The leaf uniformly distributing mechanism comprises a leaf uniformly distributing device and a lifting driving assembly. The leaf uniformly distributing device includes a shifting arm, a rotary table and a rotary table driving assembly. The lifting driving assembly can drive the leaf uniformly distributing device to move up and down. The system for fine manipulation is convenient to realize uniform distribution of leaves in the tossing machine, and allows alternating between tossing and setting, to realize continuous and automatic fine manipulation for tea leaves. It can significantly reduce labor intensity and improve production efficiency, while improving stability of oolong tea quality.

The present disclosure relates to a system and a method for fine manipulation. The system for fine manipulation includes a tossing mechanism, a setting mechanism, and a leaf uniformly distributing mechanism. The tossing mechanism comprises a tossing machine, a leaf distributing assembly, a first feeding conveyor assembly, and a first receiving conveyor assembly. The setting mechanism comprises a setting assembly, a second feeding conveyor assembly, and a second receiving conveyor assembly. The setting assembly includes a setting belt and a setting belt driving device configured to drive the setting belt to move. The leaf uniformly distributing mechanism comprises a leaf uniformly distributing device and a lifting driving assembly. The leaf uniformly distributing device includes a shifting arm, a rotary table and a rotary table driving assembly. The lifting driving assembly can drive the leaf uniformly distributing device to move up and down. The system for fine manipulation is convenient to realize uniform distribution of leaves in the tossing machine, and allows alternating between tossing and setting, to realize continuous and automatic fine manipulation for tea leaves. It can significantly reduce labor intensity and improve production efficiency, while improving stability of oolong tea quality.