A harvester having a frame, an agitating system and a product gathering system. The frame has a central portion configured to receive and pass plants therethrough. The agitating system is positioned within the central portion that has a first side agitating assembly further comprising an axle with an axis of rotation and a plural of axial wands extending axially outwardly therefrom in a spaced apart configuration. The axle has a first end which is both above and outboard of the second end and the axle is angled relative to a vertical plane bisecting the frame body from front to back thereof. The axial wands can be agitated. The product gathering system includes an outer guide wall positioned below the rotary agitator assembly. The outer guide wall is angled relative to a vertical plane bisecting the frame body from front to back thereof.

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. 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.

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. 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.

A shaped conveyor assembly configured for use in association with a harvester comprising a first side lower conveyor sub-assembly and a second lower conveyor sub-assembly. One or both of the sub-assemblies having a frame structure, a discharge assembly and a conveyor assembly. The frame structure has a gathering portion, an outward portion and a terminating portion. The gathering portion is positioned proximate the first end and spaced apart from the second end. The terminating portion is positioned proximate the second end and spaced apart from the first end. The outward portion extends therebetween, the outward portion being inclined in an upward direction relative to the gathering portion, and directed in an outward direction, thereby extending away from the channel, and away from the other one of the first side and the second side lower conveyor sub-assemblies.

A shaped conveyor assembly configured for use in association with a harvester comprising a first side lower conveyor sub-assembly and a second lower conveyor sub-assembly. One or both of the sub-assemblies having a frame structure, a discharge assembly and a conveyor assembly. The frame structure has a gathering portion, an outward portion and a terminating portion. The gathering portion is positioned proximate the first end and spaced apart from the second end. The terminating portion is positioned proximate the second end and spaced apart from the first end. The outward portion extends therebetween, the outward portion being inclined in an upward direction relative to the gathering portion, and directed in an outward direction, thereby extending away from the channel, and away from the other one of the first side and the second side lower conveyor sub-assemblies.

A row unit for a header of an agricultural harvester is provided. The row unit includes a frame, a first deck plate assembly mounted to the frame, and a second deck plate assembly mounted to the frame. The first and second deck plate assemblies each include a deck plate, a plurality of deck plate segments extending from the deck plate and moveable between a first position and a second position relative to the deck plate, and a plurality of biasing members for biasing each respective deck plate segment. The row unit includes both operator controlled macro adjustment and automatic micro adjustment of a gap between the first deck plate assembly and the second deck plate assembly. The micro adjustment is achieved through biasing members biasing each respective deck plate segment.

Apparatuses for and methods of moving the ends of windrows inward are disclosed. The apparatuses of the present invention include a front end, a rear end and two opposing sides, the front end configured to be wider than the rear end, two skids attached to the two opposing sides, a gate rotatably attached to the rear end and configured to cover an opening in the rear end, a gate cylinder operably attached to the gate and configured to close the gate to collect fruit and/or nuts within the apparatus, and open the gate to distribute the fruit and/or nuts outside of the apparatus, thus eliminating the need to hand rake the ends of the windrows inward or to blow the ends of the windrow inward with a hand blower.

Apparatuses for and methods of moving the ends of windrows inward are disclosed. The apparatuses of the present invention include a front end, a rear end and two opposing sides, the front end configured to be wider than the rear end, two skids attached to the two opposing sides, a gate rotatably attached to the rear end and configured to cover an opening in the rear end, a gate cylinder operably attached to the gate and configured to close the gate to collect fruit and/or nuts within the apparatus, and open the gate to distribute the fruit and/or nuts outside of the apparatus, thus eliminating the need to hand rake the ends of the windrows inward or to blow the ends of the windrow inward with a hand blower.

Disclosed is a portable telescopic push-pull vibrating-shaking type Camellia oleifera fruit picking and beating machine. The machine includes a picking and beating head, a gear shifting mechanism, a power transmission and picking and beating rod, a direct current motor, a control system, a handheld grip, and a lithium battery. A battery supplies power to enable the direct current motor to rotate, the direct current motor drives a worm and worm wheel mechanism in the gear shifting mechanism to rotate through a power transmission rod, the worm and worm wheel mechanism drives the picking and beating head to achieve reciprocating push-pull motion, such that the picking and beating rod can pull a branch to generate push-pull and vibration to pick Camellia oleifera fruit down. The picking and beating head is provided with a force sensor capable of monitoring picking and beating strength at any time.

A method to adjust an opening between a plurality of shakers of a machine formed as a fruit harvester, starting with aligning and centralizing the machine with a crop row to be harvested, includes the steps of: identifying and defining a configuration of a plurality of trees to be harvested; measuring a width of the plurality of trees to be harvested; setting a value for a desired damage level; calculating an opening factor based on the desired damage level defined in the step of setting; determining a distance X from the opening between the plurality of shakers, based on a value obtained for the opening factor in relation to the width of the plurality of trees to be harvested; and adjusting the opening between the plurality of shakers according to the distance X determined in the step of determining.