DE4343281A1 - Method of transferring loose goods into pneumatic conveyor - Google Patents

Abstract

The loose material is withdrawn from the transfer chamber with a constant conveying pressure and is conveyed by a gas flow. One of the exchange chambers of the transfer chamber periodically conveys the loose material by means of a pressure equalisation and then the gas is drawn away. The discharged gas is then compressed and fed into the conveying gas stream. The gas discharge pipe (8a) of the exchange container (4) is connected by a pump (9) to the feeder gas pipe (3). The pump on the suction side can be connected via a reversing valve (14) to the gas discharge pipe and to an accumulator container (15). A non-return valve (16) is connected in parallel with the reversing valve. The gas feeder pipe (8b) of the exchange container is connected by a locking valve (17) to the pressure side of the pump. The pump is connected to a compressive force machine in parallel with a pressure reduction valve (12) of the feeder gas pipe.

Description

The invention relates to a method for transferring bulk material to a pneumatic conveyor system, the bulk goods from a constant with the discharge pressure deducted transmission room and by a Conveying gas flow is promoted, and being one Medium upstream exchange room Pressure compensation periodically bulk material is fed.

This procedure for the transfer of bulk goods to a pneumatic conveyor system is known (DE-OS 38 30 544.5).

Since the bulk goods to be loaded usually with Ambient pressure is promoted and there in the pneumatic conveyor system and in the connected Transmission room there is an increased delivery pressure, the Exchange space can be brought to this increased pressure when the general cargo is fed into the broadcasting room.

The bulk material can be for example by means of a piston, a screw or another mechanical device in the room higher Pressure. The necessary pressure equalization is taken over by this pushing device. Except for inevitable leakage leaks no feed gas here, but is a high one Energy expenditure for penetrating the bulk material  required because the bulk material against the upcoming Delivery pressure must be pushed. Also kick relatively strong wear effects on the Pushing device on.

Another known method is that Inject bulk goods into the conveyor system. For this is basically a lock chamber is required, which in periodic process picks up the bulk material and then opened to the pneumatic conveyor system becomes. This flows under the delivery pressure Conveying gas into the lock chamber from which in opposite direction the bulk material in the under Parts of the conveyor system that are under pressure. After the lock chamber opposite the conveyor is finished again, it must be Delivery gas relaxes to and from the ambient pressure Lock chamber can be drained when this again with Bulk material is filled. An exchange takes place between the conveying gas under increased pressure and the bulk material supplied with ambient pressure. At Known cellular wheel sluices form the individual cells each a lock chamber in which the described Exchange process plays.

Because of their small number of moving parts compared to rotary feeders such devices for Passing bulk goods advantageous, the two have containers connected in series, namely one ending in the pneumatic delivery line Transmission container and one via a shut-off valve upstream exchange container, which acts as a lock chamber acts and in which the pressure equalization is carried out. This exchange container is periodically filled with bulk goods filled, closed and constantly under the Delivery pressure standing transmission container opened. That under Pressurized conveying gas penetrates from the transmission container  the exchange container, and the bulk material enters opposite direction in the transmission container. It is advantageous to equalize the pressure before opening the Shut-off valve between exchange and transmission container, there no back-flowing gas hinders the bulk material inflow and rapid wear, especially on the shut-off valve is avoided with large pressure differences. Before the The feed gas must be refilled be removed from the replacement container.

The amount of the conveying gas that is used for pressure equalization in the lock chamber, in the special case in the Exchange container, has occurred and for example on the ambient pressure has been released stands for Funding process no longer available. Except for the Gas loss also occurs in most cases also the difficulty that the gas discharged with increased effort must be disposed of because it is either is contaminated by abrasion material of the bulk material or is a gas, for example a protective gas, which is not without further can be derived into the environment. Of the the effort required for this is considerable.

The object of the invention is therefore a method of train the type mentioned so that at Pressure equalization, no conveying gas escapes.

This object is achieved in that the gas discharged from the exchange space is compressed and the Conveying gas flow is supplied.

Since no production gas escapes, there are none Difficulty in disposing of contaminated and / or harmful gas; there is also no loss Conveying gas.  

It from the exchange room is particularly advantageous removed gas before supply to the conveying gas stream to save. This ensures that the gas quickly from the Exchange room can be drained while it is Production gas flow distributed over a larger period of time can be supplied.

It has proven to be particularly useful that Removing the gas from the exchange space by generating a vacuum in one to the exchange room connected storage space. This will particularly quick emptying of the exchange space reached, at the same time the supply of bulk material to the Exchange space is accelerated.

Are there large spaces and a discontinuous Bulk goods supply, such as for pressure vessels, see above can be the time until pressure equalization is reached Redirecting the gas over the storage space can be shortened without the pumping power having to be increased for this. The Gas under pressure in the exchange room flows alone due to the pressure drop to the storage space.

A particularly advantageous embodiment of the invention is characterized in that the increased pressure of the supplied feed gas to the pressure of the feed gas stream is reduced that the pressure drop in the conveying gas in mechanical energy is implemented and that the so energy gained to compress the from the exchange room withdrawn and supplied to the conveying gas stream is used.

Because in most cases the pressure of the gas supplied is higher than that required to convey the bulk material Pressure and therefore a pressure reduction is necessary, it will existing pressure drop as drive energy for the  Pumping process used without external energy must be supplied.

The method according to the invention is common to all devices for the transfer of bulk goods to a pneumatic Conveyor system can be used in which an exchange room as Lock chamber is used, for example also at Cell wheel locks.

The invention also relates to an advantageous device to carry out the procedure.

Starting from a device with a sending container, the one connected to a production gas line pneumatic delivery line opens, and with a Transmit container upstream via a shut-off valve Exchange container that has a shut-off valve with a Bulk feed line is connected and gases in and Has gas outlet line is the invention Device characterized in that the gas supply and Gas outlet pipe of the exchange container via a pump is connected to the feed gas line. The pump compresses that from the gas outlet line of the Exchange gas escaping conveying gas on the Delivery pressure and leads it to the delivery gas line or the Exchange container in case of pressure increase too.

Further advantageous embodiments of the The idea of the invention is the subject of further Subclaims.

The following is an embodiment of the invention explained in more detail, which is shown in the drawing.

It shows:

Fig. 1 is a simplified diagram of an apparatus for transferring bulk material to a pneumatic conveyor,

Fig. 2 is a simplified representation of the pump used in the device of FIG. 1 and

Fig. 3 is a greatly simplified view of the constructive structure of the device of FIG. 1.

In the device shown in FIG. 1, a closed transmission container 1 opens into a pneumatic delivery line 2 . A conveying gas line 3 is connected to the conveying line 2 and supplies the conveying gas flow necessary for the conveying.

A closed exchange container 4 is connected upstream of the transmission container 1 via a shut-off valve 5 . A bulk material feed line 6 is connected to the exchange container 4 via a shut-off valve 7 .

From the exchange container 4 is a gas line 8 , which branches into a gas outlet line 8 a and a gas supply line 8 b, is led out and is connected to the feed gas line 3 via valves and a pump 9 and a line 10 to be described later.

In a gas line 11 , gas under increased pressure is brought up, which is expanded via a pressure reducing valve 12 to the delivery pressure required in the connected delivery gas line 3 . A shut-off valve 13 is provided in the conveying gas line 3 .

The pump 9 can be connected on the suction side via a changeover valve 14 designed as a 3/2-way valve either to the gas outlet line 8 a of the exchange container 4 and to a storage container 15 . A check valve 16 is connected in parallel with the changeover valve 14 and can be flowed through in the flow direction from the pump suction side to the storage container 15 and blocks in the opposite direction.

The gas supply line 8 b of the exchange container 4 is connected via a shut-off valve 17 to the pressure side of the pump 9 , which is connected to the conveying gas line 3 via a line section 18 .

The operation of the device so far described is as follows:

The bulk material flows into the exchange container 4 via the shut-off valve 7 . After closing the shut-off valve 7 and switching the changeover valve 14 into its other position (not shown here), the gas from the storage container 15 and the gas line 11 is also partly supplied via the pressure reducing valve 12 via the shut-off valve 17 and the pump 9 . After the pressure equalization between the expansion tank 4 and the transmission tank 1 , the bulk material passes through the shut-off valve 5 into the transmission tank 1 , from which the delivery through the delivery line 2 begins.

If the exchange container 4 is emptied and the shut-off valves 5 and 17 are closed again, the changeover valve 14 switches over to the position shown in FIG. 1. The gas flows from the exchange container 4 via the gas outlet line 8 a and a subsequent line 19 and via the changeover valve 14 and the check valve 6 into the storage container 15 and into the pump 9 .

The pump 9 generates a fore vacuum in the exchange container 4 , so that after the shut-off valve 7 has opened, the bulk material can flow to the environment more quickly as a result of the pressure difference generated. The memory 15 serves to shorten the time until pressure equalization is achieved when using a relatively small pump 9 . The reduction in time for the pressure equalization of the exchange container 4 with the environment (lower value) for the inflow of the bulk material is achieved by the relaxation in the storage container 15 . A pre-vacuum in the storage container 15 is advantageous here. In contrast, a time reduction is achieved by the gas line 11 via the pressure reducing valve 12 for the pressure equalization between the expansion tank 4 and the transmission tank 1 (upper value). In the exchange container 4 , a pressure equalization is carried out before the supply and the transfer of the bulk material into the transmission container 1, which is under delivery pressure, by removing or supplying delivery gas.

In the illustrated embodiment, the pump 9 is connected to a pressure engine, which is connected in parallel to the pressure reducing valve 12 of the feed gas line 3 and is driven by the pressure reduction of the feed gas supplied. For this purpose, the pump 9 and the pressure engine are designed as a tandem piston-cylinder unit 20 ( FIG. 2). A double-acting pump piston 21 alternately compresses the gas discharged from the exchange container 4 on its two piston sides. The pump piston 21 is connected by a common piston rod 22 to a notor piston 23 , which is acted upon alternately by the supplied conveying gas on its two piston sides.

A 5/2-way valve 25 is switched over by limit switches 24 , which detect the pump piston 23 in its two end positions, in such a way that one of the two cylinder spaces 26 , 27 is acted upon alternately with the increased pressure from the gas line 11 . At the same time, the other cylinder side 27 or 26 is connected via the 5/2-way valve 25 to the line 10 leading to the conveying gas line 3 . The motor piston 23 driven in this way is part of a pressure engine which is connected in parallel to the pressure reducing valve 12 and uses the pressure reduction of the conveying gas as an energy source.

Depending on its stroke direction, the working piston 21 draws gas from the changeover valve 14 via a check valve 28 or a check valve 29 via a line 30 and presses it in its opposite stroke via a changeover valve 31 or 32 into the line 10 leading to the conveying gas line 3 . The gas is sucked in either from the exchange container 4 or from the storage container 15 via the 3/2-way valve 14 .

Fig. 3 shows that the storage container 15 is designed as at least one closed hollow column carrying the expansion tank 4 and the transmitter tank 1 , which stands on a base plate 33 . Together with this base plate 33 , the columnar storage container 15 , which for example can also consist of two columns, forms a stable holder for the device.

Claims (11)

1. A method for transferring bulk material to a pneumatic conveyor system, the bulk material being withdrawn from a transmission space that is constantly subjected to the delivery pressure and conveyed by a flow of conveying gas, and wherein bulk material is periodically supplied and gas is removed from an exchange space upstream of the transmission space by means of pressure compensation, characterized in that that discharged from the gas exchange chamber is compressed and the conveying gas flow is supplied. 2. The method according to claim 1, characterized in that the gas discharged from the exchange room before the supply to the gas flow is stored. 3. The method according to claim 1 or 2, characterized characterized in that the removal of the gas from the Exchange space by creating a vacuum in one storage space connected to the exchange space.   4. The method according to any one of claims 1-3, characterized characterized in that the increased pressure of the supplied Production gas reduced to the pressure of the production gas stream will that the pressure reduction of the production gas in mechanical energy is implemented and that the so energy gained to compress the from the exchange room withdrawn and supplied to the conveying gas stream is used. 5. An apparatus for performing the method according to any one of claims 1-4, with a transmission container which opens into a pneumatic delivery line connected to a conveying gas line, and with an exchange container upstream of the transmission container via a shut-off valve, which is connected via a shut-off valve to a bulk material feed line and has a gas supply and gas outlet line, characterized in that the gas outlet line ( 8 a) of the exchange container ( 4 ) is connected via a pump ( 9 ) to the conveying gas line ( 3 ). 6. The device according to claim 5, characterized in that the pump ( 9 ) on the suction side via a switching valve ( 14 ) optionally with the gas outlet line ( 8 ) of the exchange container ( 4 ) and with a storage container ( 15 ) can be connected. 7. The device according to claim 6, characterized in that the switching valve ( 14 ) is a check valve ( 16 ) is connected in parallel, which can be flowed through in the direction of flow from the pump suction side to the storage container ( 15 ) and blocks in the opposite direction. 8. The device according to claim 5, characterized in that the gas supply line ( 8 b) of the exchange container ( 4 ) via a shut-off valve ( 17 ) is connected to the pressure side of the pump ( 9 ). 9. The device according to claim 5, characterized in that the pump ( 9 ) is connected to a pressure engine, which is connected in parallel to a pressure reducing valve ( 12 ) of the feed gas line ( 3 ) and is driven by the pressure reduction of the feed gas supplied. 10. The device according to claim 9, characterized in that the pump ( 9 ) and the pressure engine are designed as a tandem piston-cylinder unit ( 20 ) that a double-acting pump piston ( 21 ) on its two piston sides alternately discharged from the exchange container Gas compresses and that an engine piston ( 23 ) connected to the pump piston ( 21 ) by a common piston rod ( 22 ) is alternately acted upon by the supplied conveying gas on its two piston sides. 11. The device according to claim 6, characterized in that the storage container ( 15 ) is designed as at least one the expansion tank ( 4 ) and the transmission container ( 1 ) carrying closed hollow column.