A scale and a fruit collector with connected rows of scales is provided. The rows of scales extending between an intake and an outlet of the collector parallel to a median axis of the collector, scales including respectively a succession of scales with overlap, mounted as pivots on a support with a return to a resting position, each scale presenting a longitudinal median scale axis extending from the proximal to distal end of the scale and forming, in the resting position, an acute angle of aperture with the median axis, relative to the collector intake, and in which each scale presents a capability to pivot relative to the support, between the resting position and at least one bent-back position towards the outlet of the collector, reducing the angle of aperture. At least one hindrance limits an amplitude of divergent displacement, respectively between two successive scales of a row of scales.

The present disclosure discloses a walking power control system for wolfberry picking, including a frame, a turntable, rotating rods, first gears, second gear, gear racks, supporting rods, hydraulic motors, a front traveling wheel, a left traveling wheel and a right traveling wheel. In the present disclosure, hydraulic motors rotate to drives three traveling wheels to rotate, thereby driving the frame to move, when it is necessary to turn, a turntable is rotated, the turntable rotates to drive two first gears to rotate, and the two first gears rotate to drive the supporting rods to rotate, thereby driving the left traveling wheel and the right traveling wheel to rotate, so that the traveling direction of the frame is changed. The picking speed of wolfberries is greatly improved, thereby improving the working efficiency and saving a lot of human resources.

The present disclosure discloses a walking power control system for wolfberry picking, including a frame, a turntable, rotating rods, first gears, second gear, gear racks, supporting rods, hydraulic motors, a front traveling wheel, a left traveling wheel and a right traveling wheel. In the present disclosure, hydraulic motors rotate to drives three traveling wheels to rotate, thereby driving the frame to move, when it is necessary to turn, a turntable is rotated, the turntable rotates to drive two first gears to rotate, and the two first gears rotate to drive the supporting rods to rotate, thereby driving the left traveling wheel and the right traveling wheel to rotate, so that the traveling direction of the frame is changed. The picking speed of wolfberries is greatly improved, thereby improving the working efficiency and saving a lot of human resources.

The present disclosure relates to the use of an aeroponic propagator for the cultivation of plants. The aeroponic propagator of the present disclosure may be a human intervention free system. The aeroponic propagator of the present disclosure may allow the total spectrum of all stages of plant growth from seedling to harvest and multi-cropping per system with minimum human intervention. The aeroponic propagator comprises a self-harvesting system for collecting produce from cultivated plants, wherein the self-harvesting system is configures to collect produce that has detached from the cultivated plants.

The present disclosure relates to the use of an aeroponic propagator for the cultivation of plants. The aeroponic propagator of the present disclosure may be a human intervention free system. The aeroponic propagator of the present disclosure may allow the total spectrum of all stages of plant growth from seedling to harvest and multi-cropping per system with minimum human intervention. The aeroponic propagator comprises a self-harvesting system for collecting produce from cultivated plants, wherein the self-harvesting system is configures to collect produce that has detached from the cultivated plants.

A leaf collection assembly for collecting leaves falling from a tree includes a collar that is positionable around a trunk of a tree. A plurality of arms is provided and each of the arms is coupled to and angles upwardly from the collar when the collar is positioned around the trunk of the tree. A screen is attached to the collar and each of the arms such that the screen forms a cone when the collar is positioned around the trunk of the tree. In this way the cone captures leaves falling from the tree. A pair of chutes is provided and each of the chutes is coupled to the collar. Each of the chutes is aligned with the cone to direct the leaves outwardly from the cone for bagging the leaves.

The present invention relates to a harvesting machine comprising a shaking mechanism operable to shake fruit or nuts from a tree or bush; a deflection plate for directing the fruit or nuts to an area away from the base of the tree or bush; and a device for moving fruit or nuts from the base of the tree or bush to the area away from the base of the tree or bush. The deflection plate may be positioned at an angle of between 0 to about 75 relative to the horizontal.

The present invention relates to a harvesting machine comprising a shaking mechanism operable to shake fruit or nuts from a tree or bush; a deflection plate for directing the fruit or nuts to an area away from the base of the tree or bush; and a device for moving fruit or nuts from the base of the tree or bush to the area away from the base of the tree or bush. The deflection plate may be positioned at an angle of between 0 to about 75 relative to the horizontal.

An autonomous agricultural vehicle including a wheel-set operably connected with a power source, a processing unit having a memory unit, and a controller operable to receive and transmit signals to the processing unit, wherein the controller is operable to control the wheel-set. The autonomous agricultural vehicle further including a wireless communication system electrically connected with the processing unit, a global positioning satellite receiver electrically connected with the processing unit, a first perception sensor electrically connected with the processing unit, wherein the first perception sensor is operable to detect environmental features, and a second perception sensor electrically connected with the processing unit, wherein the second perception sensor is operable to detect a feature of a tree. Wherein the processing unit is operable to navigate an environment utilizing signals from the global positioning satellite receiver, and wherein the processing unit is operable to navigate the environment utilizing signals from the first and second perception sensors in a GPS denied environment.

An autonomous agricultural vehicle including a wheel-set operably connected with a power source, a processing unit having a memory unit, and a controller operable to receive and transmit signals to the processing unit, wherein the controller is operable to control the wheel-set. The autonomous agricultural vehicle further including a wireless communication system electrically connected with the processing unit, a global positioning satellite receiver electrically connected with the processing unit, a first perception sensor electrically connected with the processing unit, wherein the first perception sensor is operable to detect environmental features, and a second perception sensor electrically connected with the processing unit, wherein the second perception sensor is operable to detect a feature of a tree. Wherein the processing unit is operable to navigate an environment utilizing signals from the global positioning satellite receiver, and wherein the processing unit is operable to navigate the environment utilizing signals from the first and second perception sensors in a GPS denied environment.