A particulate material delivery system for an agricultural implement including, an inductor box configured to receive particulate material from a tank, the inductor box including, an inductor segment comprising a particulate material supply chamber configured to guide the particulate material toward a fluidization chamber, and an air supply chamber configured to receive airflow from an airflow supply, wherein the inductor box is configured to direct the airflow from the air supply chamber to the particulate material supply chamber through a first airflow path and through a second airflow path remote from the first air path.

A system includes a product delivery tube having an air inlet, an agricultural product inlet, and an exit nozzle. The agricultural product inlet is disposed between the air inlet and the exit nozzle, and the first product delivery tube is configured to receive the agricultural product from the agricultural product inlet, and to use an air flow received by the air inlet to convey the agricultural product through the exit nozzle. The system also includes a drop tube configured to receive the agricultural product, and to convey the agricultural product at a drop tube angle to the agricultural product inlet. The drop tube angle is formed by a junction between the first drop tube and the first product delivery tube, and the drop tube angle is greater than approximately 0 degrees and less than approximately 90 degrees relative to the product delivery tube.

A system includes a solids combining system with a solids mixing section having a mixing chamber and a plurality of solids inlets configured to supply one or more solids into the mixing chamber. The system also includes a solids breakup section having a plurality of fluid inlets configured to supply one or more fluids into the mixing chamber and a solids flow control section having a converging-diverging passage downstream of the mixing chamber.

A material collection unit for a material handling system is disclosed. The material collection unit includes an elongated housing section, a separator, and an accumulation bin. The separator is disposed within the housing section and partially bisects the elongated housing section into first and second sections. The first section is in communication with an inlet for materials to pass through. The second section is in communication with an exhaust. The accumulation bin is disposed below the elongated housing and has an open top section that is in communication with the elongated housing section and a second opening that is configured to mate with an opening of a baler unit.

A material collection unit for a material handling system is disclosed. The material collection unit includes an elongated housing section, a separator, and an accumulation bin. The separator is disposed within the housing section and partially bisects the elongated housing section into first and second sections. The first section is in communication with an inlet for materials to pass through. The second section is in communication with an exhaust. The accumulation bin is disposed below the elongated housing and has an open top section that is in communication with the elongated housing section and a second opening that is configured to mate with an opening of a baler unit.

A snow conveying assembly for use with a snow making machine includes an impeller for receiving snow from the snow making machine and accelerating the snow; and an ejector tube, which receives the snow from the impeller, further accelerates the snow and discharges the snow from the assembly. The ejector tube contains a venturi throat. Snow from the impeller is conveyed via a snow inlet tube into the ejector tube immediately upstream of a venturi throat and air under pressure is blown into the ejector tube upstream of the venturi throat to further accelerate the snow.

A snow conveying assembly for use with a snow making machine includes an impeller for receiving snow from the snow making machine and accelerating the snow; and an ejector tube, which receives the snow from the impeller, further accelerates the snow and discharges the snow from the assembly. The ejector tube contains a venturi throat. Snow from the impeller is conveyed via a snow inlet tube into the ejector tube immediately upstream of a venturi throat and air under pressure is blown into the ejector tube upstream of the venturi throat to further accelerate the snow.

A machine for blowing a loose-fill insulating product, includes at least a base and a pipe for transporting the insulating product, the base including at least an air inlet, an inlet for loose-fill insulating product and an outlet connected to the pipe, the pipe including at least one cylindrical wall which delimits a space configured for the passage of the loose-fill insulating product and the air, the blowing machine including at least one evacuation orifice formed through the cylindrical wall of the pipe, the at least one evacuation orifice being configured to allow the passage of air toward the exterior of the pipe and block the passage of the loose-fill insulating product.

The present invention relates to a particle transfer system and a particle transfer method which allow preciously-weighed particles to smoothly pass through a vertically-provided vertical pipe of a transfer line when powder-type particles are transferred along the transfer line, and which prevent the particles from remaining or stagnating in the vertical pipe. To this end; the particle transfer system includes a particle transfer unit including at least one from among: a first transfer unit for transferring the particles in correspondence to first transfer information; a second transfer unit spaced from the first transfer unit to transfer the particles in correspondence to second transfer information, which is the same as or different from the first transfer information; and a third transfer unit spaced from the first transfer unit and the second transfer unit to transfer the particles in correspondence to third transfer information, which is the same as or smaller in amount than the first transfer information or the second transfer information.

The present invention relates to a particle transfer system and a particle transfer method which allow preciously-weighed particles to smoothly pass through a vertically-provided vertical pipe of a transfer line when powder-type particles are transferred along the transfer line, and which prevent the particles from remaining or stagnating in the vertical pipe. To this end; the particle transfer system includes a particle transfer unit including at least one from among: a first transfer unit for transferring the particles in correspondence to first transfer information; a second transfer unit spaced from the first transfer unit to transfer the particles in correspondence to second transfer information, which is the same as or different from the first transfer information; and a third transfer unit spaced from the first transfer unit and the second transfer unit to transfer the particles in correspondence to third transfer information, which is the same as or smaller in amount than the first transfer information or the second transfer information.