DE3644119A1 - Method for pneumatically conveying material to be conveyed, and apparatus for controlling the air feed therefor - Google Patents

Abstract

A method and an apparatus for pneumatically conveying material to be conveyed in a tube-like conveying line into which compressed gas is introduced from a connection line are improved in that, in the case of a pressure increase in the conveying line, in the conveying direction before the connection line or its mouth, the conveying line is opened for air feed from a secondary line at high pressure, and in that, in the case of pressure equalisation in the conveying line in the region before and after the mouth of the connection line, this air feed into the conveying line is interrupted. For this purpose, a slide is provided as a control element in the connection line, blocks the latter in a basic position and is arranged in a flow space between a first and a second sensor line, the other end of each of which sensor lines opens, at a different side to the connection line, into the conveying line and is connected, via a throttle section, to that segment of the connection line leading to the secondary line.

Description

The invention relates to a method for the pneumatic conveying of material to be conveyed in a tube-like conveying line, into which - preferably transversely to the conveying direction - compressed gas is introduced from a connecting line. In addition, the invention relates to a device for controlling the air feed from a secondary line through a connecting line into a delivery line of a pneumatic conveyor system, the connecting line being closable by a control element with an energy store , in particular a coil spring.

The plugs belonging to the dense phase conveying process Funding is used to protect bulk goods as gently as possible with low speed and low discharge pressure to transport through a pipe. Special meaning has this funding process for abrasive or abrasive sensitive products. Because larger throughputs with smaller ones Air volumes can be reached, the energy remains cost low.

At the beginning of a conveyor line the bulk material only little conveying air added, it forms itself Plugs separated by air cushions are. Especially on bends of the delivery line  but push the plugs together while conveying the finally reach such a length that the Delivery pressure to maintain the transport of goods not enough anymore. In addition, the pressure to Pushing a plug not only by its length, but also depends on the plug porosity; especially for bulk goods with a wide grain spectrum there are plugs of different porosity.

It is known that by feeding air into the Plugs the air pressure necessary to promote it significantly lower. Various devices are available for this have been proposed.

DE-PS 33 23 739 describes a connection line tion, which ver. by a spring-loaded membrane can be closed; this membrane is located between two air spaces and under the influence of one Coil spring. According to the teaching of DE-PS 33 23 739 a variety of pneumatically connected shut-off valves Chambers and membranes required; you only give to the Place additional conveying air in the delivery line which is just now a plug and loosens this on. The air is then and there in plugs and Blown membranes when the differential pressure between two adjacent shut-off valves a predetermined Value exceeds.  

A disadvantage of such an apparatus is that always a plurality of shut-off valves are required even if only at a certain point of the feed line - for example on a sheet - the loosening effect of the injected jet of air would be required. In addition, the membrane must be able to withstand the differential pressure between two feed points, as a result of which the device reacts sluggishly.

Another disadvantage is that the system Membrane / spring / air pressure is undamped, causing the Membrane not with appropriate pressure conditions fully opens, but begins to flutter. The at open netem valve seat from the secondary line through the shut-off Air flowing to the delivery line also acts on the membrane, so that its loading does not change can only result from the pressure of the delivery line.

In another conception, as is offered for example by DE-PS 30 24 568, air is blown into the delivery line at certain intervals - continuously or at intervals. This also happens at points on the conveyor line where there is no material to be conveyed. It is disadvantageous that the amount of conveying air in the conveyor - and thus the conveying speed - increases constantly and the conveying air is not optimally used. By gradually expanding the delivery line, attempts are made relatively unsuccessfully to compensate for the increase in speed.

In view of this state of the art, the He finder set the goal, a procedure and a device tion of the type mentioned at the beginning with which the recognized disadvantages of the known methods and pre directions are avoided.

To solve this problem, the idea that Pressure increase in the delivery line in the direction of delivery connected to a secondary line with high pressure Connect this by one from the Delivery line directly to the connecting line open air flow for the compressed gases to open as well if there is pressure in the delivery line in the area and after the connection pipe opens, this Interrupt air supply again.

The connecting line runs between the funding office tion and a - higher pressure than the delivery line leading - branch line and is managed by one by one Energy storage held in a defined basic position Tax body kept closed until in the funding office pressure increases. Then moves according to the invention the controller at a higher pressure in a first Sensor line against the force of the energy storage so that compressed air from the secondary line into the delivery line flows; with equal pressure in the first and one control element goes back into the second sensor line his basic position back. So according to the invention as Control unit a slide in the connecting line in front seen who locks them in a basic position as well in a flow space between the first and the second - on the other at different Sides of the connecting line into the delivery line denden - sensor line is arranged.  

According to another feature of the invention, each is the Sensor lines via a throttle section to the Branch line leading section of the connecting line connected, these throttle sections narrow cross cut preferably parallel to that flow space longitudinal bore of a housing block.

The slide advantageously consists of two through a section of narrower cross-section, in particular pistons connected at a distance by a slide rod bodies with - from the dislocation dimension of the line sections of the connecting line certain - axial Store play in the longitudinal bore and from which to at least one of the piston bodies against the axially acting Energy storage supports, the section being narrow cross cut, so the slide rod, in one against the Energy storage guided open position of the shooting bers releases the connecting line.

It is within the scope of the invention that the mouths of the sections of the connector separable by the slide line or connected to these sections Cross bores of the housing block in the longitudinal bore an axial dimension to each other laterally - i.e. with respect to of the transverse bores are radially offset, which one is less than the axial length of that slide rod and ensures that there is a clear separation between the basic position of the slide and its open position consists.

The design of the control member in the form of a housing block with a longitudinal bore for the slide throttle bores for the sensor lines is of simple construction and yet of great effectiveness. It requires the use of a single device of this type in order to guarantee the control of the entire conveying process. In contrast to the known state of the art , the sensor lines that open into the conveying line on one side of the connecting line each represent parts of a branch line Delivery line. This branch line crosses the connecting line outside the longitudinal bore, but is also connected to the ends with air.

Further advantages, features and details of the inven tion result from the following description of a preferred embodiment and with reference to the drawing; this shows in Figure 1 is the schematic longitudinal section through an inventive device with a control member in its basic position.

FIG. 2 shows the longitudinal section, enlarged compared to FIG. 1, through the control element;

FIGS. 3 and 4, the device according to Fig. 1 in two different operating positions thereto.

From a conveyor line 10 with a diameter d for bulk material moving in the direction x , a connecting line 12 branches off at right angles, which, with the interposition of a control element 14, on the other hand opens into a secondary line 16 with a section 12 _e ; whose diameter e speaks here approximately to the fifth part of the diameter d of the delivery line 10 .

The control member 14 has a housing block 20 of length f and a width b which is shorter than this and has a longitudinal bore 22 for a slide 24 ; the latter consists of two bolt-like piston bodies 27 , 28 connected by an axial slide rod 26 , one of which is axially drilled out and receives one end of a helical spring as an energy store 30 in a blind bore 29 .

This protrudes from the piston body 28 and is supported at the other end against an end plate 32 _e which is fixed to the housing block 20 and closes that longitudinal bore 22 at one end - a corresponding end plate 32 covers the other end of the longitudinal bore 22 .

In the basic position of the slide 24 shown in Fig. 1, the coil spring ( 30 ) receiving the piston body 28 is at a distance h from the adjacent end plate 32 _e , and closes one of the longitudinal bore 22 - in Fig. 2 upwards - Outgoing cross bore 34 , to which the section 12 _{e of} the connecting line to the secondary line 16 connects (thread 35 ); offset by a dimension q , a second transverse bore 36 runs parallel to the transverse bore 34 between the longitudinal bore 22 and the other section 12 of the connecting line.

In the basic position of the slide 24, the transverse bore 36 opens into an annular space 38 of the axial length i, which is determined by the longitudinal bore 22 and the axial slide rod 26 and is sealed in the basic position to the other transverse bore 34 . The two transverse bores 34 and 36 are thus separated from each other in this position by the piston body 28 .

Parallel to the longitudinal bore 22 , narrow ducts of a diameter r of preferably 1 mm, as a throttle section 40 , extend from both sides of the upper transverse bore 34 , each of which merges into a coaxial bore 42 of larger diameter t . These bores 42 each open into a first or a second sensor line 44 or 45 , which at different distances s or n to the connecting line 12 at 54 or 55 reach the delivery line 10 ( FIGS. 1, 4).

The pressure prevailing in the secondary line 16 air pressure P _NL is higher than the pressure P _FL in the delivery line 10, which - in the basic position of the slide 24 is ge thanks to the piston body 28 of the sub-line 16 separates - as described. Increases, for example, by a plug 50 approaching in the delivery line 10, the pressure P ₁ in the first sensor line 44 - which, on the one hand, is connected via its throttle section 42 to the upper section 12 _{e of} the connecting line and, on the other hand, at 46 to the longitudinal bore 22 -, the slide 24 moves against the force of the coil spring 30 in the conveying direction x until the annular space 38 both Querbohrun conditions 34 , 36 - and thus both sections 12 _e , 12 of the connecting line - detected: from the secondary line 16 , compressed air P _{NL flows} in the delivery line 10 ( Fig. 3).

If the plug 50 to which compressed air has been applied has passed the mouth 13 of the connecting line 12 and the mouth 55 of the second sensor line 45 , the pressure in both sensor lines 44 , 45 is equalized again, and the slide 24 slides back into its basic position.

A very small amount of air flows through the sensor lines 44 , 45 and is taken from the secondary line 16 and its quantity is determined by the throttle sections 40 .

The points 13 and 54 , 55 , where the loosening air or the air passed through the throttle sections 40 are fed, are protected by filters not shown in the drawing for reasons of clarity, so that no dirt particles in the longitudinal bore when the device is switched off 22 or can reach the slide 24 .

Lapped metal slides without soft seals are particularly suitable as slides 24 , which are already at pressures of 2 KP. (Kilopascal) move, so that the desired differential pressure for switching is determined by the power of the energy store. Of course, slider 24 with soft seals or rolling membranes can also be used.

The drawing does not show that a Pressure screw for adjusting the spring force attached can be.

Claims (12)

1. A method for the pneumatic conveying of conveyed material in a tubular conveying line, in which - preferably transversely to the conveying direction - from a connecting line device, compressed gas is introduced, characterized in that when the pressure in the conveying line increases in the conveying direction in front of the connecting line or its mouth, the latter Air supply from a secondary line is opened at high pressure, and that this air supply into the delivery line is interrupted when the pressure in the delivery line is equalized in the area before and after the connection line opens. 2. Device for controlling the air feed from a secondary line through a connecting line into a delivery line of a pneumatic conveyor system, the connecting line being closable by a control element with an energy store, in particular with a spring, in particular for carrying out the method according to claim 1, characterized in net by a slide ( 24 ) as a control element in the connecting line ( 12 , 12 _e ), which blocks it in a basic position and is arranged in a flow space ( 22 ) between a first and a second sensor line ( 44 and 45 ), each of which is at the other end another side of the connecting line opens into the delivery line ( 10 ) and is connected via a throttle section ( 40 ) to the section ( 12 _e ) of the connecting line leading to the secondary line ( 16 ). 3. Apparatus according to claim 2, characterized in that each sensor line ( 44 and 45 ) outside its throttle section ( 40 ) is directly (at 46, 46 _e ) connected to the flow chamber ( 22 ). 4. Apparatus according to claim 2 or 3, characterized by a slide ( 24 ) with at least two through a section ( 26 ) narrower cross-section from ( i ) connected piston bodies ( 27 , 28 ) which form the flow space with axial play in one store the longitudinal bore ( 22 ), and of which at least one against the axially acting energy storage ( 30 ) is supported, the portion of narrower cross section in a position against the energy storage ge led the slide, the connecting line device ( 12 , 12 _e ) releases . 5. Device according to one of claims 2 to 4, characterized in that the mouths ( 34 , 35 ) of the separable by the slide ( 24 ) sections ( 12 _e , 12 ) of the connecting line in the longitudinal bore ( 22 ) by an axial dimension ( q ) are offset from one another, which is less than the axial length ( i ) of the slide section ( 26 ) of narrower cross section. 6. Apparatus according to claim 4 or 5, characterized in that the piston body ( 27 , 28 ) are connected by an axial slide rod ( 26 ) which forms an annular space ( 38 ) with the wall of the longitudinal bore ( 22 ). 7. The device according to at least one of claims 2 to 6, characterized in that the coming from the delivery line ( 10 ) section ( 12 ) of the connecting line in the basic position of the slide ( 24 ) in the then sealed annular space ( 38 ) or the like. opens and the other section ( 12 _e ) of the connecting line is closed by the piston body ( 28 ) attached to the energy store ( 30 ). 8. The device according to at least one of claims 2 to 7, characterized in that the longitudinal bore ( 22 ) extends in a housing block ( 20 ) and with the release of end connections ( 46 and 46 _e ) with the sensor lines ( 44 and 45 ) through end plates ( 32 , 32 _e ) is closed. 9. Device according to one of claims 2 to 8, characterized in that an end plate ( 32 _e ) serves as an abutment for the energy store ( 30 ) and this protrudes into a blind hole ( 29 ) of the adjacent piston body ( 28 ). 10. The device according to at least one of claims 2 to 9, characterized in that the sensor lines ( 44 and 45 ) in the delivery line ( 10 ) open at different axial distances ( s and n ) to the connecting line ( 12 ). 11. The device according to at least one of claims 2 to 10, characterized by a slide ( 24 ) made of lapped piston bodies ( 27 , 28 ). 12. The device according to at least one of claims 2 to 11, characterized in that the diameter ( r ) of the throttle sections ( 40 ) running parallel to the longitudinal bore ( 22 ) is approximately 1 mm.