DE693692C - by means of compressed air and bulk material storage to carry out the process - Google Patents

Description

Process for ventilating bulk material storage using compressed air and Bulk material storage for carrying out the process. The invention relates to a method for ventilating bulk solids reservoirs by means of compressed air, in which, the Air intake and discharge by means of horizontal ventilation ducts alternately on opposite sides Pages of the memory takes place in their entire length.

In a known method of this type, the air is used for discharge sucked off and thus a flow of air essentially only in the horizontal direction causes what, if .this also an intensive ventilation is achieved, as a result of "that the perimeter of space covered by the air flow in both directions of flow the air is always the same, spaces remain, those of the air are not just empty are insufficiently flowed through.

In contrast, the invention aims to keep such spaces in this way to: avoid that with each reversal of the air flow the previous one Not or only insufficiently ventilated part of the storage tank filling in the main is flowed through by the air, so that finally the total content of the memory with the least amount of technical equipment; namely ventilation ducts, at all Places is adequately ventilated.

This ventilation process assumes that the natural law Compressed air to take the path of least resistance within the material to be ventilated endeavors, therefore, the shortest route to the given discharge points, and only with such lateral deviations from the direction to the take-off point, which correspond to the easier overcoming of the flow resistance. Shall the air Deduction options in accordance with this natural legal situation be given in different directions of flow, this presupposes that the air extraction points from the air inflow point in different directions are approximately the same distance. At the same time it is a condition that on all Discharge points the same pressure conditions prevail, namely that not at the one or the other conceivable extraction point as a result of suction using a fan o. The like. There is a negative pressure, which means that the air flows in the direction of excludes the other withdrawal points.

Accordingly, found in the process of the invention the introduction and discharge of air near the floor or there and at ventilation level height, the discharge also at the upper end of the storage, on the surface of the storage contents instead, whereby the Aüs @: - conduct only takes place as a result of the overpressure alet air, at a distance from the discharge point that is approximately the height of the dump - or corresponds to the ventilation level, so that the air both in the transverse direction as well as free deduction in height direction. "In another known method the compressed air is removed from the sieve-like perforated bottom or cover of the bulk material container from alternately in both directions through the container. Here the total content of the container is covered by the air flowing through it, however is this method for the ventilation of high storage tanks because of the in this case occurring .high flow resistance not suitable.

The drawing represents several exemplary embodiments According to the invention, ventilation set up memory represents. FIG. 1 shows a memory in vertical section, FIG. the Fig.3, q. and 5 show further embodiments of memories in vertical section; Fig. 6 is a plan view of FIG. 5 and FIG. 7 a memory in a diagrammatic representation Adoption of see-through walls. The direction of flow of the air is when the air is introduced Air on one side by full arrow lines and at the introduction indicated on the other side by dashed arrow lines.

In FIGS. I and 2, the basic form of a storage tank intended for the type of ventilation according to the invention is shown, for example. In the store, a horizontal ventilation duct f, fl is arranged on both sides near the floor. The distance between these two ventilation ducts running the full length of the storage tank corresponds approximately to the filling height of the storage tank, so that the flow resistance for the air between these channels is approximately the same as from the bottom to the surface of the storage tank contents. The ventilation process consists in that the Dtuckluft first from one of the two ventilation ducts, for. B. f, flows into the memory and through. A smaller part of this is drawn horizontally with corresponding lateral deviations to the other ventilation duct fi and from this through the vertical shaft a at the upper end of the storage tank into the open air, while the greater part of the air takes its way upwards in both vertical and inclined flow directions and also - At the upper end of the storage tank, the air is withdrawn only as a result of excess pressure, i.e. without suction using a fan or the like. In the following work process, the compressed air is then supplied through the ventilation duct f1, which was previously used for air discharge, from which the air escapes to the smaller part to the horizontally opposite ventilation duct f and from this through the vertical shaft b at the upper end of the storage tank, while the larger part the air takes its way up again in both vertical and inclined directions of flow and also escapes into the open at the upper end of the storage tank. The amount of air flowing vertically upwards with corresponding lateral deviations is, depending on the part of the space covered by it in this direction, relatively slightly larger than the amount of air that pulls upwards in oblique directions, which is compensated by the fact that in the two Work processes cross the diagonal flow directions of the air. The two ventilation ducts f, f1 can be connected to the compressed air line s, as shown, for example, from below. The control of the ventilation ducts for air supply and exhaust, as shown in Fig. I shown, for example, be done by means of piston 1z in vertical shafts a, b and are from sliding, such that each time a piston at the foot of the relevant shaft, the blocks with the same connected compressed air line s below the relevant ventilation duct. whereas in the other ventilation duct, by adjusting the piston above the same, the access of the compressed air is released. This arrangement can advantageously be further simplified for operation in that the pistons are arranged on a common rope t running over pulleys r , as can be seen in FIG. Instead of the piston, other locking means, e.g. B. flaps, are used, such as those in the embodiments according to FIGS. Q. and 5 (locking flaps q, p) are arranged.

In FIG. 2, in view of the memory length which is always arbitrarily large several mutually offset vertical shafts a., b shown.

The Fig.3, q. and FIG. 5 show representations of memories one above the other ventilation levels located (Fig. i shows a single such).

Two opposite horizontal ventilation channels e, f are arranged at the foot of each ventilation level. In the case of such stores, a simplification can take place in such a way that, as shown, ventilation ducts which can be switched for supply and exhaust air on both sides f with ventilation ducts intended only for exhaust air. e alternate, with a switchable channel on one side opposite a channel intended only for exhaust air on the other side. How the air flows run in this case is shown in FIG. 3 for a memory with two ventilation levels, in FIG. 4 for one with three ventilation levels and in FIG for the other work process indicated by dashed arrow lines. Similar to the illustration in FIG. 1, part of the air flows across the shaft and the other in the vertical direction of the same, in order to escape into the open at the upper end of the storage tank. Similar to there, the arrangement is also made in these designs such that the distance between two channels e, f located opposite one another at the same height is approximately the same as the distance between these channels and the channels above them; that is, roughly the same as the ventilation level, or, as far as the top two channels are concerned, that the distance between these channels is roughly the same as their distance from the surface of the storage content, so that in these designs the flow resistance for the air from the inlet point to the different rejection points is approximately the same. Here, too, vertical air shafts a, b with pistons h are arranged. In this case, the piston in the shafts limits the height to which the compressed air has to reach in order to reach all the ventilation ducts f in question by means of its setting. The above-described simplification of the operating option by means of a cable guide r, t between two pistons located in mutually opposite shafts is, as shown, also applicable here. While one of these pistons blocks the relevant air shaft at a suitable height and below the air inlet permitted, the piston in the other air duct is in such a low position that the compressed air cannot reach a ventilation duct f connected to this duct, with the part of the air duct above the piston set in this way being released for exhaust air Stores that have more than two ventilation levels, which may be the case, are, as shown in Fig..5, according to the invention, air diversion channels g arranged in the air shafts a, b at the desired height, -which enable the exhaust air to bypass the piston lock : 'Compressed air lines can, as indicated in Fig. 4 and 5, Absperrkla ppen q and p can be arranged to regulate the air supply. 6 and 7 show the type of connection of the ventilation ducts f, e with the air ducts a, b, c, d arranged at the four corners, with air diversion ducts g being arranged at two air ducts a, b .

Instead of the ventilation ducts that are only suitable for exhaust air, one would consistently Arrange switchable ventilation ducts for supply and exhaust air everywhere, so you would be in the Able to use the memory in more than two, namely in three or four operations to ventilate all the more thoroughly. With every work process, the air currents would give a different picture.

Claims (4)

PATENT CLAIMS; i. Process for ventilating bulk storage facilities by means of compressed air, in which the inlet and outlet of the air by means of horizontal Ventilation ducts alternate on opposite sides of the memory throughout Length expansion takes place, characterized in that the introduction and discharge the air close to the ground or there and at the height of the ventilation level, as well as the discharge takes place at the upper end of the memory, on the surface of the memory contents, whereby the discharge only takes place as a result of the overpressure of the air, namely at a distance from the discharge point, which is approximately the dump height or the Ventilation level corresponds to, so that the air both in Ouerrichtung and has free deduction in height direction. . 2. Bulk material storage for carrying out the process according to claim i, characterized in that for introducing and discharging the air in the distance from each other specified in claim i, alternating for air introduction and air discharge switchable ventilation ducts (f, f1) are arranged. 3. bulk material storage according to claim 2 with two or more ventilation stages, characterized in that on both sides for air inlet and air outlet switchable and nux for air outlet certain ventilation ducts (f, e) alternate with each other, with a switchable ventilation duct on one side only for air outlet certain ventilation duct is opposite on the other side. 4. Bulk material storage according to claim 2 and 3, in which the ventilation ducts are connected to vertical air shafts containing control pistons, characterized in that the air shafts (a, b) are provided in the intended .Höhe with air bypass channels (g), which enable the piston lock to be bypassed . Bulk material storage device according to claims to q., Characterized in that the control pistons are connected to one another in two air shafts each by a common cable (t) guided over pulleys (y).