Electronic soil coping system applied to a grain harvesting platform, able to adjust working height parameters during the collection process, adapting itself to soil irregularities and to those generated by uprooting, increasing the efficiency and reducing loss, enabling to combine belt collection at any time, individually, in pairs, or all of them jointly, generating different physical states, which will vary according to the number of belts of the device, also allowing the platform to perform tailpieces at street ends, not collecting undesired materials, and also allowing to increase the width of collection belts.

A replacement blade for a sickle bean harvester, having a flat base, an axis of movement, and a base plane, and attaches to a sickle bar in at least four blade positions. The blade includes four teeth extending in a direction perpendicular to the axis with a triangular shape where the first side extends at an angle from the base and includes a first cutting surface on a first cutting plane that is oblique from the base plane and a first series of cutting edges within the first cutting surface, and the second side extends at an angle from the base and meets the first side at a point, with a second cutting surface on a second cutting plane that is oblique from the base plane, and has a second series of cutting edges within the second cutting surface, and the third side is integral with and abuts the base.

A replacement blade for a sickle bean harvester, having a flat base, an axis of movement, and a base plane, and attaches to a sickle bar in at least four blade positions. The blade includes four teeth extending in a direction perpendicular to the axis with a triangular shape where the first side extends at an angle from the base and includes a first cutting surface on a first cutting plane that is oblique from the base plane and a first series of cutting edges within the first cutting surface, and the second side extends at an angle from the base and meets the first side at a point, with a second cutting surface on a second cutting plane that is oblique from the base plane, and has a second series of cutting edges within the second cutting surface, and the third side is integral with and abuts the base.

A defoliator having a frame suitable for mounting to a vehicle supports an elongated main support arm which extends substantially horizontally, and which has a tine-bearing main shaft which rotates to have the tines knock at least some leaves (or portions thereof) from plants beneath. The main support arm rides on wheels, and may pivot and vertically translate with respect to the frame such that the main support arm (and the tined main shaft) will generally follow the elevation and contour of the ground beneath. To defoliate greater areas, one or both ends of the main shaft may be connected to a boom arm hearing a rotating tined arm shaft, which extends the effective length of the main support arm and tined main shaft. The boom arms are preferably capable of folding rearwardly to reduce the effective size of the defoliator for easier transport.

A defoliator having a frame suitable for mounting to a vehicle supports an elongated main support arm which extends substantially horizontally, and which has a tine-bearing main shaft which rotates to have the tines knock at least some leaves (or portions thereof) from plants beneath. The main support arm rides on wheels, and may pivot and vertically translate with respect to the frame such that the main support arm (and the tined main shaft) will generally follow the elevation and contour of the ground beneath. To defoliate greater areas, one or both ends of the main shaft may be connected to a boom arm hearing a rotating tined arm shaft, which extends the effective length of the main support arm and tined main shaft. The boom arms are preferably capable of folding rearwardly to reduce the effective size of the defoliator for easier transport.

The present application for patent of invention refers to equipment designed for harvesting, cleaning and storing farming produce. The farming produce it is designed to process particularly includes peanuts, beans or any other produce disposed in rows that can be gathered from the ground. The invention comprises a head (2), endowed with a collecting platform (3) with belts (5); the head (2) comprises a transmission box (4) of the dual and pivotable type; the head (2) has complete hydraulic system with hydraulic oil tank (9), heat exchanger (9A) and filters; said transmission box (4) further has auxiliary input (11) to couple an accessory that can be hydraulic; pneumatic or electric, in order to drive auxiliary systems; in the rear part of the equipment are helicoids (6) that extend to the vertical transporter (7) and latter to the container (8).

A system for modifying a row unit of a harvesting head, the system including at least one cutting disk, a right angle gear set configured for being drivingly connected to the cutting disk, and a drive shaft between a row unit gear box and the right angle gear set. The system may drive two counter-rotating cutting disks that can be positioned either at near the rear or the front of the row unit. A method for modifying the row unit includes removing existing stalk rolls and housings, installing a cover plate over a gearbox to which the housings were mounted, removing existing trash knives, drilling holes in the row unit frame for mounting the cutting disks, installing the cutting disks.

The present invention relates to a multicrop header comprising a chassis (1), which comprises a kinematic chain (8) linked to a module selected from a cutter bar module (a) and a stripper module (b). This kinematic chain (8), powered by the harvester feeder, drives the rotor (f) embedded in the cutter bar module (a) or the command tire (7) embedded in the stripper module (b). The cutter bar (a) and stripper (b) modules are fixed to the sides of the chassis (1) using a single plurality of bolts (6) inserted in holes shared by both modules. The cutter bar module (a) includes a reel (c) mounted by a set of brackets (e) placed at the top of the chassis (1). The same set of brackets (e) attached to the chassis (1) allows the deflector (h) of the stripper module (b) to be mounted.

The present invention relates to a multicrop header comprising a chassis (1), which comprises a kinematic chain (8) linked to a module selected from a cutter bar module (a) and a stripper module (b). This kinematic chain (8), powered by the harvester feeder, drives the rotor (f) embedded in the cutter bar module (a) or the command tire (7) embedded in the stripper module (b). The cutter bar (a) and stripper (b) modules are fixed to the sides of the chassis (1) using a single plurality of bolts (6) inserted in holes shared by both modules. The cutter bar module (a) includes a reel (c) mounted by a set of brackets (e) placed at the top of the chassis (1). The same set of brackets (e) attached to the chassis (1) allows the deflector (h) of the stripper module (b) to be mounted.

Electronic soil coping system applied to a grain harvesting platform, able to adjust working height parameters during the collection process, adapting itself to soil irregularities and to those generated by uprooting, increasing the efficiency and reducing loss, enabling to combine belt collection at any time, individually, in pairs, or all of them jointly, generating different physical states, which will vary according to the number of belts of the device, also allowing the platform to perform tailpieces at street ends, not collecting undesired materials, and also allowing to increase the width of collection belts.