A pneumatic conveying apparatus operable to transport material from a supply source to a process which requires a rate of change of feed rate far in excess of what is possible from a typical pneumatic conveying system and pipeline alone, and for a process where storage of large volumes of material directly adjacent to the process feed point is either not possible or disadvantageous. The pneumatic conveying apparatus (100; 101;102) comprises at least one conduit (11) and a compression device (8) operable to supply and transport pneumatic media through at least one conduit (11). The supply source (1) may be a feed hopper and is operable to discharge material into the pneumatic conveying system downstream of the supply source. In the pneumatic conveying system at least one vessel (9; 9A, 9B; 20) is arranged to receive material from the supply source (1) and to discharge material to at least one conduit (11). The system also includes a filter receiver (4), which is configured to simultaneously receive and discharge material and pneumatic media from at least conduit. The filter receiver has a working volume or capacity which is very small in relation to the feed rate, typically 1 to 2 minutes storage when operating at the maximum discharge rate, and with a volume typically th to th of the volume of the vessels feeding material into the start of the pneumatic conveying pipeline. The filter receiver is equipped with a discharge device operable to increase the discharge rate to the process from the minimum feed rate to the maximum feed rate in a time period of 2 to 30 seconds. The filter receiver (4) is configured and operable to separate material and pneumatic media such that the material can be discharged from the filter receiver to the downstream process (2), in order to separate the conveying apparatus from the process and provide further advantages described within the invention. The apparatus includes a control system (19) that is operable to maintain a target weight and/or level within the filter receiver, and recover the target weight and/or level in the filter receiver, by measuring the weight and/or level and the rate of change of weight or level, of all storage vessels discharging material to the pneumatic conveying pipeline and process and incorporating aspects of closed loop control methodologies.

An ejection hood apparatus includes a transfer conduit and a hood. The transfer conduit includes a downwardly concave control shell. An inlet end portion of the transfer conduit receives an upwardly directed transfer air stream including ejected material with at least a partially upward trajectory. The hood defines an ejection chamber including a lower chamber portion and an upper chamber portion. The lower chamber portion receives the transfer air stream from an outlet end portion of the transfer conduit with at least a partially downward trajectory. The hood includes at least one air outlet passage communicated with the upper chamber portion for exhausting at least a portion of the transfer air stream.

An ejection hood apparatus includes a transfer conduit and a hood. The transfer conduit includes a downwardly concave control shell. An inlet end portion of the transfer conduit receives an upwardly directed transfer air stream including ejected material with at least a partially upward trajectory. The hood defines an ejection chamber including a lower chamber portion and an upper chamber portion. The lower chamber portion receives the transfer air stream from an outlet end portion of the transfer conduit with at least a partially downward trajectory. The hood includes at least one air outlet passage communicated with the upper chamber portion for exhausting at least a portion of the transfer air stream.

The invention relates to a method and a dense phase powder pump (1) for conveying coating powder from a first powder reservoir (101) to a second downstream powder reservoir or to a downstream powder spray-coating gun (102) or the like installation for spraying coating powder. In order to reduce the number of components of the dense phase powder pump (1) that require maintenance, the dense phase powder pump (1) is designed as a single-chamber dense phase powder pump and has only a single powder conveyor chamber (4) for conveying coating powder.

The invention relates to a method and a dense phase powder pump (1) for conveying coating powder from a first powder reservoir (101) to a second downstream powder reservoir or to a downstream powder spray-coating gun (102) or the like installation for spraying coating powder. In order to reduce the number of components of the dense phase powder pump (1) that require maintenance, the dense phase powder pump (1) is designed as a single-chamber dense phase powder pump and has only a single powder conveyor chamber (4) for conveying coating powder.

A delivery system deposits granular material being pneumatically conveyed within an entraining airflow to sequentially fill a storage silo from bottom to top. The delivery system has a series of vertical tubes and separators, vertically suspended and centered within the silo by a support, for conveying the entrained material upwardly from the bottom to the top of the silo. Each separator selectively separates the material from the airflow by choking the airflow entraining the material therewithin. Each separator automatically selects either to separate the entrained material therewithin and to deposit the separated material therefrom, or else to flow therethrough the entrained material without separation. The support has clamp assemblies, each having clamp halves and clamp brackets, wall brackets, and braces.

A delivery system deposits granular material being pneumatically conveyed within an entraining airflow to sequentially fill a storage silo from bottom to top. The delivery system has a series of vertical tubes and separators, vertically suspended and centered within the silo by a support, for conveying the entrained material upwardly from the bottom to the top of the silo. Each separator selectively separates the material from the airflow by choking the airflow entraining the material therewithin. Each separator automatically selects either to separate the entrained material therewithin and to deposit the separated material therefrom, or else to flow therethrough the entrained material without separation. The support has clamp assemblies, each having clamp halves and clamp brackets, wall brackets, and braces.

A method for transferring barite for use in wellbore fluids may include providing a ground weight material comprising barite and quartz having a d.sub.50 between about 4 and 8 and a d.sub.90 between about 15-25 microns to a pneumatic transfer vessel, supplying an air flow to the ground weight material in the pneumatic transfer vessel, and pneumatically transferring the ground weight material from the pneumatic transfer vessel to a storage vessel.

Disclosed is a grain conveying apparatus using air, the apparatus efficiently collecting foreign materials while moving grains upward to a position at which the grains are easily fed into a grain processing machine by using the suction force air, and preventing shock so as to prevent damage to the grains. The grain conveying apparatus using air, according to the present invention, comprises: a grain supply hopper for accommodating the grains; a conveyer pipe for guiding the grains supplied from the grain supply hopper and the air flowing in from an external air inlet such that the grains, by means of the air suction force, and the air are moved together; a grain discharge pipe connected to the end of the conveyer pipe; a separation pipe for separating the grains and the foreign materials, the separation pipe comprising a horizontal part connected to the grain discharge pipe and a downwardly curved part for dropping the grains; a rotary valve connected to the lower part of the curved part of the separation pipe so as to discharge the grains in predetermined amounts; an exhaust pipe for discharging the separated foreign materials to the outside; and an air suction means having a ring blower connected to the end of the exhaust pipe so as to suck the air, wherein the front end of the grain discharge pipe is provided to penetrate the lower side of a finishing plate for closing a coupled part of the separation pipe, an inner diameter of the grain discharge pipe and an inner diameter of the separation pipe are formed to be small in a ratio of 0.4 to 0.5:1 such that the internal pressure of the separation pipe is lowered due to a change in the pressure difference, and a cut inclined surface, to be inclined in the direction of the grain conveyer pipe, is formed at the lower part of the front end of the grain discharge pipe, so as to cover the upper part thereof in order not to be influenced by the air discharged to the exhaust pipe connected to the upper side of the separation pipe, and allows the grains to be discharged to the lower side of the horizontal part of the separation pipe having a large inner diameter.

An apparatus for collecting dust from a cutting unit is provided. The apparatus includes a rotary valve operatively connected to the cutting unit, a conduit in fluid communication with the rotary valve, and a compacting machine disposed downstream from the conduit and configured to receive dust from the conduit. A blower is configured to pull air downstream to carry the dust into the compacting machine. The compacting machine produces a compact from the dust.