A process for pressurizing bulk material in a hopper; wherein the hopper is configured as a lock hopper (29) containing a bulk material, a source of pressurized gas, lines (22, 26, 28) to convey the pressurized gas from the source to one or more inlets (30) of the lock hopper, a valve arranged in the lines, wherein the opening position of said valve (34, 35) is controlled to provide pressurizing gas to the lock hopper at a preset constant gas volume flow rate.

A process for pressurizing bulk material in a hopper; wherein the hopper is configured as a lock hopper (29) containing a bulk material, a source of pressurized gas, lines (22, 26, 28) to convey the pressurized gas from the source to one or more inlets (30) of the lock hopper, a valve arranged in the lines, wherein the opening position of said valve (34, 35) is controlled to provide pressurizing gas to the lock hopper at a preset constant gas volume flow rate.

There is herein described an adjustable multi-hole orifice plate in a pneumatic conveying apparatus. More particularly, there is described an adjustable multi-hole orifice plate which can be used in a pneumatic conveying apparatus to assist in the discharge of material.

A pneumatic distribution system to distribute a granular product to an agricultural implement includes a first pressure sensor, a second pressure sensor, a valve, and a controller. The first pressure sensor is fluidly coupled to a granular product storage tank and outputs a first signal indicative of a first static pressure in the storage tank. The second pressure sensor is fluidly coupled to a primary line that pneumatically delivers the granular product to the agricultural implement by guiding an air stream from a first section with a larger cross-sectional area to a second section with a smaller cross-sectional area. The second pressure sensor outputs a signal indicative of the static pressure in the second section of the primary line. The valve is fluidly coupled between the storage tank and the primary line and selectively enables the air stream to flow from the primary line to the storage tank. The controller, which is communicatively coupled to both pressure sensors and the valve, instructs the valve to enable the air stream to flow from the primary line to the storage tank until the first static pressure is greater than the second static pressure by a threshold amount.

A system for transporting hazardous particles includes a pneumatic conveyer for conveying the hazardous particles to an exit using a carrier gas; and an input mechanism for conveying the hazardous particles to the pneumatic conveyer. The input mechanism includes a tubular chamber for receiving the hazardous particles; an input pipe extending from the tubular chamber for conveying the hazardous particles into the tubular chamber; and an output pipe extending from a bottom of the tubular chamber. The output pipe includes an upper valve movable between a closed position and an open position, a middle valve movable between a closed position and an open position, and a lower valve. The upper valve and the middle valve, when in their respective closed positions, define a storage chamber for storing a portion of the hazardous particles. The upper valve in its open position allows the portion of the hazardous particles to enter the storage chamber, and the middle valve in its open position allows the portion of the hazardous particles in the storage chamber to flow to the lower valve. The lower valve is configured to convey the hazardous particles from the storage chamber to the pneumatic conveyer in a gradual fashion.

A system for transporting hazardous particles includes a pneumatic conveyer for conveying the hazardous particles to an exit using a carrier gas; and an input mechanism for conveying the hazardous particles to the pneumatic conveyer. The input mechanism includes a tubular chamber for receiving the hazardous particles; an input pipe extending from the tubular chamber for conveying the hazardous particles into the tubular chamber; and an output pipe extending from a bottom of the tubular chamber. The output pipe includes an upper valve movable between a closed position and an open position, a middle valve movable between a closed position and an open position, and a lower valve. The upper valve and the middle valve, when in their respective closed positions, define a storage chamber for storing a portion of the hazardous particles. The upper valve in its open position allows the portion of the hazardous particles to enter the storage chamber, and the middle valve in its open position allows the portion of the hazardous particles in the storage chamber to flow to the lower valve. The lower valve is configured to convey the hazardous particles from the storage chamber to the pneumatic conveyer in a gradual fashion.

Methods and systems for transferring feed materials between zones having substantially different pressures, where the transfer can be continuous or semi-continuous. The methods and systems include a plurality of lock hoppers to receive feed material from a low pressure zone and pressurize it with fluid to a pressure of a high pressure zone. The pressurized material can be discharged to a circulation loop, which carries the pressurized material to one or more receiving unit(s) of a pressurized system. At least some feed material remains in the receiving unit(s) and at least a portion of the fluid exits to become part of the circulation loop. After discharge, the lock hoppers can be depressurized so the next pressurization cycle can begin with additional feed material. The lock hoppers can be operated in a time-staggered manner to provide continuous or semi-continuous transfer of material.

Methods and systems for transferring feed materials between zones having substantially different pressures, where the transfer can be continuous or semi-continuous. The methods and systems include a plurality of lock hoppers to receive feed material from a low pressure zone and pressurize it with fluid to a pressure of a high pressure zone. The pressurized material can be discharged to a circulation loop, which carries the pressurized material to one or more receiving unit(s) of a pressurized system. At least some feed material remains in the receiving unit(s) and at least a portion of the fluid exits to become part of the circulation loop. After discharge, the lock hoppers can be depressurized so the next pressurization cycle can begin with additional feed material. The lock hoppers can be operated in a time-staggered manner to provide continuous or semi-continuous transfer of material.

The present invention relates to a smart granular raw material conveyance system and a smart granular raw material conveyance method, wherein, when granular materials in powder form are conveyed along a conveyance line, the precisely metered granular materials are smoothly passed through a vertical pipe vertically installed in the conveyance line, and the granular materials are prevented from remaining or stagnating in the vertical pipe. The smart granular raw material conveyance system comprises at least one of: a first conveyance unit that conveys the granular materials in an amount corresponding to a first conveyance amount; a second conveyance unit that is spaced apart from the first conveyance unit and conveys the granular materials in an amount corresponding to a second conveyance amount equal to or different from the first amount; or a third conveyance unit that is spaced apart from the first conveyance unit and the second conveyance unit, and conveys the granular materials in an amount corresponding to a third conveyance amount equal to or less than the first amount or the second amount.

The present invention relates to a smart granular raw material conveyance system and a smart granular raw material conveyance method, wherein, when granular materials in powder form are conveyed along a conveyance line, the precisely metered granular materials are smoothly passed through a vertical pipe vertically installed in the conveyance line, and the granular materials are prevented from remaining or stagnating in the vertical pipe. The smart granular raw material conveyance system comprises at least one of: a first conveyance unit that conveys the granular materials in an amount corresponding to a first conveyance amount; a second conveyance unit that is spaced apart from the first conveyance unit and conveys the granular materials in an amount corresponding to a second conveyance amount equal to or different from the first amount; or a third conveyance unit that is spaced apart from the first conveyance unit and the second conveyance unit, and conveys the granular materials in an amount corresponding to a third conveyance amount equal to or less than the first amount or the second amount.