A spreader for broadcasting granular or particulate material over a surface includes a dual rotor configuration, a material deflection system, and a portable electronic device holder. The material deflection system includes components for deflecting material broadcasted by each of the rotors. The spreader includes a walking speed indicator to inform the user whether the current speed is too fast, too slow, or within an acceptable reference range.

A spreader having a hopper for particulate material with discharge openings over two separate different areas along the hopper bottom, a pair of wheels upon separate drive shafts mounted for rotation to a lower frame which supports the hopper, and a rear frame extending from the hopper to provide a pair of handles. Two rotatable shafts with agitator elements are mounted over each of the different hopper areas. Each of the agitator shafts are coupled for rotation by different ones of the drive shafts. Two gates with openings are disposed below the hopper each along different ones of the areas dividing the hopper bottom. Each gate is movable to close and open the openings of the hopper in the area associated with the gate. A pair of controllers are provided each coupled to a different one of the two gates to independently move the gates between open and close positions.

A spreader having a hopper for particulate material with discharge openings over two separate different areas along the hopper bottom, a pair of wheels upon separate drive shafts mounted for rotation to a lower frame which supports the hopper, and a rear frame extending from the hopper to provide a pair of handles. Two rotatable shafts with agitator elements are mounted over each of the different hopper areas. Each of the agitator shafts are coupled for rotation by different ones of the drive shafts. Two gates with openings are disposed below the hopper each along different ones of the areas dividing the hopper bottom. Each gate is movable to close and open the openings of the hopper in the area associated with the gate. A pair of controllers are provided each coupled to a different one of the two gates to independently move the gates between open and close positions.

A power seeder may include a frame, one or more wheels, one or more blades capable of cutting into soil, an engine capable of powering the one or more blades, and a seed hopper. The seed hopper may have an opening capable of dispensing seed located forward of the one or more blades. The one or more blades may rotate in an opposite direction to a forward rotation of the one or more wheels. In some embodiments, the seeder may further include a handle for adjusting the height of the one or more blades, a plurality of interlocking teeth, and a spring. The spring may provide a load to counteract the force of gravity on the one or more blades. The aerator may also include a flap located between the opening and the one or more blades.

A power seeder may include a frame, one or more wheels, one or more blades capable of cutting into soil, an engine capable of powering the one or more blades, and a seed hopper. The seed hopper may have an opening capable of dispensing seed located forward of the one or more blades. The one or more blades may rotate in an opposite direction to a forward rotation of the one or more wheels. In some embodiments, the seeder may further include a handle for adjusting the height of the one or more blades, a plurality of interlocking teeth, and a spring. The spring may provide a load to counteract the force of gravity on the one or more blades. The aerator may also include a flap located between the opening and the one or more blades.

A small hand-guided self-propelled garlic planter includes a rack, a driving mechanism connected to an upright planting mechanism and a material taking mechanism in a stock bin by using a clutch mechanism. The stock bin is fixedly connected to the rack. The planting mechanism includes a material receiving mechanism fixed to the rack and an insertion type planting mechanism disposed below the material receiving mechanism. The insertion type planting mechanism is connected to a turnable mechanism mounted to the rack, which is connected to the driving mechanism. A plurality of first feed bowls are disposed on the material receiving mechanism. The first feed bowls are connected to a first opening mechanism. A first acting member is disposed on the insertion type planting mechanism. A plurality of duckbills connected to a second opening are disposed on the insertion type planting mechanism. A second acting member is disposed on the rack.

A small hand-guided self-propelled garlic planter includes a rack, a driving mechanism connected to an upright planting mechanism and a material taking mechanism in a stock bin by using a clutch mechanism. The stock bin is fixedly connected to the rack. The planting mechanism includes a material receiving mechanism fixed to the rack and an insertion type planting mechanism disposed below the material receiving mechanism. The insertion type planting mechanism is connected to a turnable mechanism mounted to the rack, which is connected to the driving mechanism. A plurality of first feed bowls are disposed on the material receiving mechanism. The first feed bowls are connected to a first opening mechanism. A first acting member is disposed on the insertion type planting mechanism. A plurality of duckbills connected to a second opening are disposed on the insertion type planting mechanism. A second acting member is disposed on the rack.

A pull behind orchard fertilizing device includes a hopper, a main frame, a wheel assembly, a material discharging assembly, a gear box, and a spreader. The hopper is mounted onto the main frame. The wheel assembly is rotatably mounted to the main frame. The material discharging assembly is integrated into the hopper so that the fertilizer that is stored within the hopper can be discharged into the spreader. The spreader is terminally mounted to the main frame and positioned below the hopper. The gear box is mounted to the main frame so that the wheel assembly can be operatively coupled with the material discharging assembly and the spreader through the main gear box, wherein discharged fertilizer from the hopper is dropped into the orchard field through the operation the spreader.

A pull behind orchard fertilizing device includes a hopper, a main frame, a wheel assembly, a material discharging assembly, a gear box, and a spreader. The hopper is mounted onto the main frame. The wheel assembly is rotatably mounted to the main frame. The material discharging assembly is integrated into the hopper so that the fertilizer that is stored within the hopper can be discharged into the spreader. The spreader is terminally mounted to the main frame and positioned below the hopper. The gear box is mounted to the main frame so that the wheel assembly can be operatively coupled with the material discharging assembly and the spreader through the main gear box, wherein discharged fertilizer from the hopper is dropped into the orchard field through the operation the spreader.

A dual-disk seed meter for a planter may include a housing defining a first seed chamber configured to receive first seeds of a first seed type and a second seed chamber configured to receive second seeds of a second seed type. The seed meter may also include a first seed disk rotatable within the housing to convey the first seeds from the first seed chamber, a second seed disk rotatable within the housing to convey the second seeds from the second seed chamber, and a drive assembly configured to simultaneously rotate the first and second seed disks. In addition, the seed meter may include a seed deflector movable relative to the first seed disk and/or the second seed disk to control which of the seed types is discharged from the housing based on a selected seed type to be delivered by the seed meter.