A plant seed harvesting device comprises a multi-layer net unit; the multi-layer net unit comprises collecting net, intermediate layer net and bottom layer net; the collecting net, the intermediate layer net and the bottom layer net are all plate-like structure having a plurality of meshes; the peripheral edge of the plate-like structure is a net frame, area with the meshes is net face; The collecting net, the intermediate layer net and the bottom layer net are arranged closely in the axial direction to form the multi-layer net unit; mesh sizes on the collecting net, the intermediate layer net and the bottom layer net are configured to be successively and gradually decreased; plant seeds can pass through the meshes of the collecting net; air but not plant seeds can pass through the meshes of the bottom layer net.

Systems and methods for replacing a removable assembly from a harvester for collecting and separating harvested crop product from twigs, dirt, dust, and other debris. A removable assembly for picking up harvested crop product and a removable assembly for separating the picked up harvested crop product from twigs, dirt, dust, and other debris are mounted to be changed out quickly in the field. A removable pickup assembly is received for removably mounting in the harvester by an inclined slot formed in a sidewall of the harvester body frame, so that the removable pickup assembly with the worn belt is lifted up and out and a replacement removable pickup assembly with a new belt is dropped into its place.

A harvest vacuum assembly includes a vacuum motor coupled to a farming implement. The vacuum motor urges air inwardly through an intake and outwardly through an exhaust when the vacuum motor is turned on. A suction tube is removably coupled to the hydraulic lift on the front end of the farming implement. The suction tube has a suction aperture therein that is directed downwardly toward ground when the suction tube is coupled to the hydraulic lift. Moreover, the suction tube is in fluid communication with the vacuum motor such that the vacuum motor urges air inwardly through the suction aperture. Thus, the suction aperture sucks loose objects on the ground for collection. The exhaust on the vacuum is in fluid communication with a harvester is towed behind the farming implement to transfer the loose objects into the harvester for harvesting.

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 sugarcane harvester including a base cutter configured to cut sugarcane from a field and a feed roller chassis, disposed adjacently to the base cutter, configured to receive the cut sugarcane. A plurality of feed roller assemblies are supported by the feed roller chassis, wherein each of the plurality of feed roller assemblies includes a roller body defining a roller body cavity, a motor support located within the roller body cavity, the motor support defining a support cavity, and a bearingless hydraulic motor disposed within the support cavity. The bearingless hydraulic motor includes a spindle extending from the motor and through the support cavity. A spindle adapter is releasably coupled to the spindle and fixedly coupled to the roller body. A roller bearing, disposed within the support cavity, includes an inner surface in contact with the spindle adapter, wherein rotation of the spindle rotates the roller body while the bearingless motor remains stationary with respect to the motor support.

A sugarcane harvester including a base cutter configured to cut sugarcane from a field and a feed roller chassis, disposed adjacently to the base cutter, configured to receive the cut sugarcane. A plurality of feed roller assemblies are supported by the feed roller chassis, wherein each of the plurality of feed roller assemblies includes a roller body defining a roller body cavity, a motor support located within the roller body cavity, the motor support defining a support cavity, and a bearingless hydraulic motor disposed within the support cavity. The bearingless hydraulic motor includes a spindle extending from the motor and through the support cavity. A spindle adapter is releasably coupled to the spindle and fixedly coupled to the roller body. A roller bearing, disposed within the support cavity, includes an inner surface in contact with the spindle adapter, wherein rotation of the spindle rotates the roller body while the bearingless motor remains stationary with respect to the motor support.

An agricultural motor vehicle able to connect to a variety of agricultural implements, and comprising a structural set having four parts: a lower chassis, an intermediate structure, a front complementary structure, and a rear complementary structure. The set is supported over a set of front traction wheels and a set of smaller rear wheels and also houses a vibrating sieve, above which is located a beating cylinder, the front edge of which connects to a concentrating guiding roller and a hinged inlet nozzle, as well as a cockpit and a grain dumper located over the set. Preceding the grain dumper is a clean grain collection gutter, a motor power set, a suction cleaning set, a clean grain elevator and lastly, a retractable side belt, whose lower edge is hinged at its midpoint and located on the upper edge of the intermediate structure.

Methods and systems for estimating volumes of agricultural crops are provided. A geographic position sensor provides positions of a harvesting machine as it gathers an agricultural crop and places the crop on the ground in a windrow. A speed of the harvesting machine is determined using the geographic position sensor. Signals are received from a sensor system disposed at a bottom of the harvesting machine. The signals are indicative of profiles of segments of the windrow on the ground. Cross-sectional areas of the windrow are estimated using the signals. Volumes of the agricultural crop are estimated using the speed of the harvesting machine and the estimated cross-sectional areas of the windrow.

Methods and systems for estimating volumes of agricultural crops are provided. A geographic position sensor provides positions of a harvesting machine as it gathers an agricultural crop and places the crop on the ground in a windrow. A speed of the harvesting machine is determined using the geographic position sensor. Signals are received from a sensor system disposed at a bottom of the harvesting machine. The signals are indicative of profiles of segments of the windrow on the ground. Cross-sectional areas of the windrow are estimated using the signals. Volumes of the agricultural crop are estimated using the speed of the harvesting machine and the estimated cross-sectional areas of the windrow.

A corn cob harvesting machine includes a tractor, cob harvester, and trailer that together lift, clean, and separate corn cobs from a corn harvester combine chaff windrow. The cob harvester has a floating cob lift immediately adjacent to and through various skirts engaging the earth that is supported by and floats with respect to a support frame. The floating cob lift has a rotary paddle that lifts and throws cobs into the first cross draft separator. The first cross draft separator has a blower that generates a vacuum within the floating cob lift. An adjustable flap intermediate between rotary paddle and blower deflects cobs and other heavier matter out of the air stream, while lighter matter is removed. A first cross draft separator removes chaff, a rock trap separates rocks, and a second cross draft separator removes additional chaff. A discharge conveyor transfers cleaned corn cobs to the trailer.