DE2024119C3 - Dry gas container - Google Patents

Description

The invention relates to a dry gas container with a movable, flexible material existing shell part, which is between the fixed container wall and a moving rigid Closing part, in particular a roof pane, arranged in a gas-tight manner and by means of at least one telescopic pipe guide is led. Such gas containers are from the Swiss patent specification 4 64 831 and the German Utility model 19 92 008 known. They differ from other gas containers, the upper one Part as a whole is designed as a telescopic part, characterized in that only a lighter movable rigid closure or The roof part is to be moved, which is sealed with a flexible Maniel part designed in the manner of a rolling membrane will. About tumbling and rolling movements To counteract this, continuous guides are provided, which, however, result in sealing problems, or it is a simple one-sided guide telescope mounted on top of the roof pane with simple sliding guides intended. Such containers are for many purposes, especially in digester gas systems, because of particularly useful due to their inexpensive construction. The increasing need for ever larger volumes nascent containers with heights of 10 m and diameters in the order of magnitude of 18 tn with simple telescopic sliding guides to guide difficulties. So so far the construction were bigger There are limits to gas containers.

The invention is based on the object of providing a gas container of the type mentioned at the outset in the manner to train that the rigid end part is easily displaceable even with large dimensions.

According to the invention it is provided that the telescopic tube guide is a lower telescopic system between the bottom of the gas container and the rigid end part and arranged against the outside of the Gas container is sealed, and has an upper telescopic system between the rigid end part and an upper part of the container is arranged. Such a guide gives even with large containers this rigid end part the necessary stability in every position. The two telescope systems together span the full container height of z. B. 10 m. If the one telescopic system is extended, the other is pushed together and vice versa, so that especially the küizire of the two Systems safely counteracts wobbling or rolling of this rigid terminating part. So it's in possible to guide the roof pane properly in all positions. If that a telescope system too unstable are threatened, the other system becomes correspondingly more stable. This interplay of two cooperating telescopes is different from simply doubling the telescopes that are too would lead to a juxtaposition, through their ingenious arrangement.

Advantageous further developments of the invention emerge from the further claims. There is still It is particularly important that, with large telescopic guides, considerable support forces are exerted on the guide elements work, these can be absorbed particularly well and permanently and the Rigid end part easily allow even over a long period of time when the tubes of the telescopic guide with each other by means of distributed over the circumference, at a distance from one another and preferably adjustable arranged, each having an approximately cylindrical peripheral surface are displaceably guided. In particular with the double telescopic system, this measure enables very large container heights and End part diameter. On the other hand, however, you can use the rather complex double telescope still in a medium size range

thereby avoiding a telescope system which is known per se and which stands on top of the roof pane now equipped with roles in the manner described above.

An embodiment of the invention is shown below described with reference to the drawings. It shows

F i g. 1 shows a longitudinal section through an inventive dry gas container with upper and lower telescopic system, in three-dimensional representation;

F i g. 2 shows a detail of the container according to FIG. 1 on a greatly enlarged scale; the In contrast to the illustration according to FIG. 1, the container is shown emptied;

3 shows a section, seen along the line III-III the fig. 2 and ij

4 shows an illustration of a telescopic guide of the container used.

F i g. 1 shows a so-called dry gas container 10, that is to say a gas container without a liquid seal, namely in longitudinal section. The container 10 has a casing I I made of sheet steel is, for example, can have a diameter and a height of iOrn and as a cylindrical Body is formed. About halfway up - that's her Sheathing 11 on its inside a circumferential flange 12, on which in not shown in detail Way, a flexible jacket part 13 is clamped in a gas-tight manner. This shell part 13 has in the fully filled state of the container 10 approximately in the shape of a truncated cone and is attached to a rigid end part in the form of a Roof pane 14 clamped in a gastight manner in a manner also not shown.

On the circumferential flange 12 are distributed over the circumference at a distance from one another obliquely upwards internally inclined bars 15 are provided, on which two rings 16 and 17 are attached one above the other. the Lattice bars 15 together with the rings 16, 17 form a rigid one attached to the casing 11 Supporting lattice work with rectangular meshes 18. This lattice work serves to support the movable casing part 13 to be supported so that overstretching and unfavorable bulges are avoided. Takes the gas content in the lower part of the container according to FIG. 1, the roof pane Ii goes up, with the movable casing part 13 in the manner of a rolling membrane * ■> unrolls on the support grid and rests against it.

If no guide were provided for the roof pane 14, this could be seen when filling and / or emptying carry out tumbling and rolling movements, with the risk that the movable casing part 13 would be damaged. For this reason there is a telescopic guide for the roof pane 14 intended.

For this purpose, a base plate 22 is welded to the base 21 of the casing 11, on which in turn two mounting rails 23, 24 (Fig. 3) welded on are. A base plate 26, which is welded to its lower end and provided with four elongated holes 25, rests first telescopic tube 27 on the mounting rails 23,24. By four screw bolts, of which in Fig. I the t> o If screw bolts 28 and 29 are shown, the base plate 26 is adjustable with the base plate 22 connected in order to enable an accurate alignment of the first telescopic tube 27.

On the outside of the first telescopic tube 27, a second telescopic tube 32 is guided by means of Rollers 33, which, as shown in Figure 4, have a cylindrical circumference and are used as roller bearings, are preferably deep groove ball bearings. It has been shown that with roller bearings one special The telescopic guide has a long service life because it does not have the tendency to create guide grooves in the tube to incorporate on which they are performed. The in Fig. 4 Rolling bearing 33 shown is guided on two side walls 34, 35, which are connected in a suitable manner to the leading pipe are welded and at the same time serve as stops in a very advantageous manner. Fig. 2 shows e.g. B. two such side walls 36 and 37, of which the lower in the empty state of the gas container 10 sits on the footplate 26, and the upper one as a stop against a stop ring 38 at the upper end of the tube 32 is used. As in Fig. 4 shown, the roller bearings 33 sit on a shaft 41, on one end advantageously a plastic washer 42 and on the other end a nut 43 and a Lock washer 44 are arranged.

The tube 32 is guided in a tube 45 which has a closure 46 at its upper end and on its lower end is provided with an annular flange 47, shown particularly clearly in FIG. 2, which in turn is connected to an annular flange 49 (Figs. 2 and 3) via an intermediary seal 48, in the bores 50 are provided for receiving fastening screws, not shown.

The annular flange 4y is, as in FIGS shown, connected to the roof pane 14 via a tubular intermediate piece 53. The tube 45 thus forms a cavity, which with the interior 54 (Fig. l) of the Gas container is in communication and is sealed to the outside. If the When the roof pane 14 lowers downwards, this tube 45 takes the Ronre 27 and 32 of the lower telescopic system into itself and thereby guides the roof pane 14. When extending, the tube 45 first slides over the tube 32, namely until the side wall 36 strikes the stop 38 (FIG. 2) and takes it with it. Then the pipe 32 extended, which is dimensioned such that it corresponds to the maximum filling of the interior 54.

In the fully filled position of the interior space 54, the lower telescopic system 27, 32 cannot be large Absorb side forces as it is fully extended. Therefore, an upper telescopic system 60 is also provided, which in this case the required Leadership guaranteed. The system 60 has an intermediate pipe 61 which is on the outside of the pipe 45 and is guided inside a guide tube receiving cap 62. A stop 63 at the upper, outer end of the intermediate tube 61 serves as a stop against a corresponding stop on the inner lower side of the tube 62. A stop 64 on the upper, outer edge of the tube 45 is also used to stop the tube 60 at a Take upward movement of the tube 45.

The cap 62 is closed at the top by a cover 65 and has a on its outside Flange 66. Her on an upper part of the casing 11, here the upper wall 67, is attached. Corresponding air passages 68 are provided between the flange 66 and the upper wall 67 in order to allow a Allow the container to breathe when the ■ Rolling membrane 13 raises and lowers.

The gas container according to the invention works as follows:

By a pipe, not shown, the Interior 54 gas supplied, or gas is removed from it. In the process, the roof pane heals or lowers 14 and that which is firmly and tightly connected to it

Tube 45.

If the roof pane 14 lowers, it pushes itself lower telescope system 27,32 together, and the upper telescope system 60 is extended. The leadership of the In this case, the roof pane 14 is mainly taken over by the lower telescopic system 27, 32.

If the container is heavily filled with gas, it will

lower telescope system 27, 32 extended, the upper telescope system 60 slides in the ro together. In this case the roof sheet is mainly held by the upper telescopic system 60 In the central position of the roof pane 14, telescopic systems contribute approximately equally to the guide bc

For this purpose 3 sheets of drawings

Claims (8)

Claims; 1. Dry gas container with a movable, made of flexible material shell part, the between the fixed container wall and a moving rigid end part, in particular a roof pane, arranged gas-tight and guided by means of at least one telescopic pipe guide, characterized in that the telescopic tube guide has a lower telescopic system (27, 32), which is arranged between the bottom (21) of the gas container (10) and the rigid end part (14) and is sealed against the outside of the gas container, and an upper telescopic system (60) comprises, which is arranged between the rigid end part (14) and an upper part (67) of the container is. 2. Gas container according to claim 1, characterized in that that the upper telescopic system (60) is attached to the rigid end part (14) so that it can be aligned Roof pane tube (45) and one over this, when it is pulled out over the roof pane tube (45) sliding telescopic tube (61) guided displaceably on an upper part (67) of the container having. 3. Gas container according to claim 1, characterized in that the lower telescopic system (27,32) is a on the bottom (21) of the container alignably fastened tube (27) which, if necessary via a or several interposed telescopic tubes (32) on the rigid end part (14) of the container is slidably guided. 4. Gasbehäk.r according to claim 2, characterized in that that the upper Telei ^ opsystem (60) with a container casing (11) or the Tubular tube receiving cap protruding from the container frame (62, 65) is provided. in which the tubes (45, 61) of the upper Tclcskopsystcms in the enter the upper end position of the rigid end part (14) and which at an upper part (67) of the Container is attached. 5. Gas container, in particular according to one of the preceding claims, characterized in that that the tubes of the telescopic guide with one another by means of distributed over the circumference, at a distance one another and preferably adjustable, each having an approximately cylindrical circumferential surface having rollers (33) are displaceably guided. 6. Gas container according to claim 5, characterized in that the rollers as rolling bearings (33) are trained. 7. Gas container according to one of the preceding claims, characterized in that at least part of the telescopic tubes with stops (36, 37, 38, 63, 64) for mutual stroke limitation is provided. 8. Gas container according to claim 7, characterized in that the stops (36, 37) as Holding members for the roller bearings (33) are formed.