EP0323946B1 - Device for maintaining large containers - Google Patents

Description

The invention relates to devices for the maintenance of large-volume containers, such as storage tanks or similar vessels, preferably with at least approximately a round cross-section according to the preamble of claim 1.

Large-capacity containers of the type of interest here are tank vessels for storing gases or liquids of all kinds, such as city gas, petroleum, various petroleum fractions and other fluids, but also solids, such as fine dusts and the like. When viewed from a central vertical axis, storage tanks of this type are mostly rotationally symmetrical structures of cylindrical, oval or spherical shape. Since their height often corresponds to several floors of a building, and because of their specific locations they are often difficult to access, their maintenance is difficult, time-consuming and therefore cost-intensive in a large number of practical applications.

The maintenance of the storage tanks, especially if they contain easily flammable, chemically aggressive or even explosive substances, is of the utmost importance and is consequently mandatory by the legislator even at relatively short intervals, even if these laws and regulations in different countries have different content.

It is known to equip large-capacity containers with commercially available constructions, such as scaffold tubes with clamp connectors, and to provide a plurality of work platforms which lie one above the other within the Scaffolding construction can be walked on using ladders. The usual boiler vessels with a circular cross-section are usually equipped in segments, that is, only over certain sub-areas of the circumferential surface, so that the necessary maintenance work on the large-volume tanks, such as renovation work or repairs of all kinds, can be carried out step by step through constant retrofitting. The scaffold structures must not be connected to the container wall in such a way that it is exposed to damage or other additional loads, for example through holes or fastening lugs. In order to produce the required stability, additional stabilizing trestles and / or support struts outside the scaffolding structure are often required in the case of scaffold structures supported at the top, in the case of often difficult subsoil conditions, such as soft sand or trench channels around the large-volume containers.

In addition to the complete scaffolding or segment scaffolding with its successively lengthy set-up assemblies, various floating platforms are also known, with a work platform practically attached to two ropes attached to a certain point on the container circumference at the upper container edge, over the height of which can be moved in the manner of an elevator. Either a hand crank provided on the work platform or an electric motor that raises or optionally lowers the suspended platform is used for this. In this case, only the small segment section of the large-capacity container predetermined by the width of the floating platform is available for repair work to disposal. Here too, the floating platform needs to be converted and re-locked from trimmed to section.

US-A-3 537 545 shows a cylindrical container arranged on a lattice mast, the convexly curved upper cover area of which carries an outwardly projecting central pin which is an integral part of this area. A scaffold construction for receiving a work platform that can be raised and lowered is attached to this pin by means of a rope and can be rotated about it. The pin must therefore absorb all of the forces transmitted via radial swivel arms of the scaffold structure and caused by the weight of the work platform, so that the container must be designed to be correspondingly stable. It is also a removable scaffold construction that must always be re-attached to the pin. It is also relatively unstable and therefore not suitable for large containers.

In addition to the difficulties outlined for the known scaffolding constructions for the maintenance of large containers, it must also be taken into account that storage tanks of this type must be provided with covers of various shapes depending on the application, such as those with central ventilation shafts or so-called dome structures, or that these are flat-bottom tanks with double walls can act.

This is where the present invention comes in, which is based on the task of being able to carry out maintenance, such as repair and / or renovation work much more easily and quickly, regardless of the type of construction, while at the same time minimizing the material required for the scaffolding construction from as few standardized individual parts as possible.

This object is achieved according to the invention by the features specified in the characterizing part of claim 1. Advantageous refinements and developments of this task solution result from the subclaims.

The fact that both the well-known floor-based complete or partial scaffolding of the open-plan container is used and above is also completely removed from a lift-like lifting platform, the above-mentioned and generally known disadvantages are completely eliminated. The maintenance device according to the invention is particularly easy to install and dismantle as an access system for storage tanks of all kinds, and easy to assemble and dismantle, it can be easily hung regardless of the location of the large-capacity container and the surrounding soil conditions around the tank over its entire length Swivel the circumference continuously, and there are no special requirements either on the container wall or on the container cover.

On ladder scaffolds suspended vertically downwards, work platforms can be inserted at any height of the scaffold construction and at the desired intervals, which in turn represent standardized individual parts. The scaffolding construction consists essentially of commercially available material already known for scaffolding of buildings and the like, namely tubular frame individual parts. For storage tanks with a central ventilation shaft or ventilation dome, one or more crane arm-like connectors are added, which are also of a material-saving design, and for large-volume vessels with fixed roofs without a central ventilation shaft, a rotating axle bearing construction, the versatility of which can also be achieved through a simple but effective construction from a few standardized individual parts indicates. The attached drawings show Various embodiments of the device according to the invention for the maintenance of large-scale containers of all types, preferably with a highly rotationally symmetrical cross section, are partially highly schematized.

Further advantages and individual features of the invention are to be explained and described in more detail as examples.

Fig. 1

die Draufsicht auf einen zylindrischen Großraumbehälter mit zentrisch fixiertem Drehgestell für die Aufnahme der Gerüstkonstruktion,

Fig. 2

die Draufsicht auf ein um einen Domschacht fixiertes Drehgestell,

Fig. 3

eine Seitendarstellung der Anordnung gemäß Fig. 2,

Fig. 4

eine Teilschnittwiedergabe mit zugehörigem Schwenkarm und Belastungsbock im Bereich der oberen Behälterwandung,

Fig. 5

die seitliche Darstellung eines möglichen Belastungsbockes

Fig. 6

eine Draufsicht eines weiteren Ausführungsbeispiels der Vorrichtung nach Fig. 3,

Fig. 7

die seitliche Darstellung eines Drehgestells für einen Großraumbehälter ohne Lüftungsdom,

Fig. 8

eine Darstellung gemäß Fig. 7 für den oberen Teil dieses Drehgestells,

Fig. 9

eine Draufsicht auf das Drehgestell gemäß Fig. 7 und 8, und

Fig. 10

eine Teildarstellung des Drehgestells von Fig. 7, den unteren Teil betreffend.

Show it:

Fig. 1

the top view of a cylindrical large-capacity container with a centrally fixed bogie for receiving the scaffolding structure,

Fig. 2

the top view of a bogie fixed around a cathedral shaft,

Fig. 3

2 shows a side view of the arrangement according to FIG. 2,

Fig. 4

a partial cut reproduction with associated swivel arm and load bracket in the area of the upper container wall,

Fig. 5

the lateral representation of a possible load frame

Fig. 6

3 shows a plan view of a further exemplary embodiment of the device according to FIG. 3,

Fig. 7

the side view of a bogie for a large container without a ventilation dome,

Fig. 8

7 for the upper part of this bogie,

Fig. 9

a plan view of the bogie according to FIGS. 7 and 8, and

Fig. 10

a partial view of the bogie of Fig. 7, relating to the lower part.

According to the embodiment of FIGS. 1 through 6, the device for the maintenance of the partially indicated cylindrical storage tank 3 essentially consists of the bogie 1 arranged centrally around the dome shaft 2, on the swivel arms leading radially outwards in the exemplary embodiment at an angle of 120 ° to each other are held, which are fixed to each other by connecting struts 5 and from on the radially outer ends of the swivel arms 12 located in the area of the upper container edge load blocks 14. On the radially outwardly extending beyond the upper container edge 7 of the swivel arms 12 are vertically hanging down the scaffolding structures holding the platforms are attached.

The bogie 1 forms a closed collar bushing around the ventilation or dome shaft 2 provided centrally on the large-capacity container.

Fig. 3 shows several details of an embodiment of a bogie, which is only indicated schematically in Fig. 1. As can be seen, in the exemplary embodiment of the ventilation shaft 2, the central holder for the scaffold structure which can be pivoted through the full angle of the container circumference. Here, the axis of rotation or symmetry is the vertical central axis 8 of the ventilation shaft, as indicated in FIG. 3 in dash-dotted lines. The bogie 1 is characterized first by the fact that the collar bushing 11 has axle stubs 13 which are guided horizontally through their vertical wall sections and on whose radially inwardly directed free ends there are mounted impellers 15 which are supported on the outer circumferential surface of the cylindrical air duct 2 while rotating of the bogie and thus the scaffolding construction. A plurality of such impellers which can be adjusted and locked in the horizontal direction by means of nuts 16 are provided around the circumferential surface of the collar bushing 11. The lower part of the display frame 1 opens into a frame 17 which can be hexagonal according to the embodiment according to FIG. 2 and quadrangular according to the embodiment according to FIG. 6. Of course, it is also possible to choose any other frame configurations for the bogie 1.

The frame 17 accommodates axle bearings via vertical bores for height-adjustable rollers or wheels 18 which run on the surface of the container roof 4 to support the bogie 1. Struts 19 can be provided between the collar bushing 11 and the frame 17 for reasons of increased strength. In their horizontal adjustability, the wheels 15 form adjusting rollers with respect to the centering of the scaffold structure, while the wheels 18 in their horizontal adjustability allow the axis-parallel alignment of the overall structure in a simple manner. On the frame 17 of the bogie 1, at least one, preferably a plurality of hinge pieces 46, which are adjustable in height and provided in the exemplary embodiment according to FIG. 4 as rectangular buffer plates and having elongated holes, which in turn hold the connecting struts 12 via bolts, are provided at regular intervals. At the radially outer ends of the connecting struts 12, a load bracket 14 is attached in the manner to be described later, which rotates along the upper container edge 7 on the container roof 4 when the bogie 1 is pivoted.

The load bracket 14 is shown again enlarged in cross section in FIG. 5. It essentially consists of a simple frame construction with lower height-adjustable wheels. However, it is also readily possible to use a carriage-like one Load block made of prefabricated pipe parts, using pipe connectors, namely pipe clamps and conventional lattice structures.

At the radially outer free ends of the extensions of the connecting struts 5 projecting beyond the container edge, as will be explained in more detail later, the ladder aisles of the scaffold structure are hooked into which the work platforms can be inserted and locked in a manner known per se as with other scaffold structures. 5 is limited in its cross section to a trapezoidal carriage construction with 4 or 8 wheels each, which can run freely around the entire surface of the large container and are able to fully absorb the weight of the scaffolding construction.

The scaffold construction according to the exemplary embodiment according to FIGS. 1 to 6 thus forms a circular construction, that is to say that it runs around the full circumferential surface of the container and runs on the container roof 4, to which ladder aisles are attached, which are able to accommodate any number of working platforms, through which in turn any place on the outer skin of the large container can be reached in the simplest way for maintenance work, such as renovations, repainting, monitoring activities and the like. It is irrelevant how many individual parts the so-called collar bushing 11 of the bogie is ultimately composed of, so that the overall construction can be constructed from only a few prefabricated and standardized individual parts. The rotary movement can be realized by means of simple chain or gear transmission drives. The conductor constructions which are attached to the radially outer ends of the swivel arms 12 are indicated in FIG. 1 with the reference number 20. Finally, it should be pointed out at this point that the swivel arm 12, as can be seen in particular in the exemplary embodiment according to FIG. 6, can also consist of a lattice construction which can have a triangular shape in cross section, for example. The device for hanging in the ladder racks or the work platforms is shown in a hint on the left in FIG. 6.

In the case of large-capacity containers or tank systems with a fixed roof construction but without a ventilation dome, the embodiment of FIGS. 1 to 6 is replaced by an embodiment as can be seen in FIGS. 7 to 10 inclusive. The dome structure is replaced here by an axle bracket 21 placed centrally on the container roof and composed of an upper part 22 and a lower part 23. The lower part 23 is connected to the upper part 22 via a plurality of shaft-like rods 24, along which a height-adjustable displacement between the upper and lower part is possible. In the exemplary embodiment, as shown in particular in FIG. 9, a total of 6 such rods 24 are provided at the same distance from the vertical central axis 8 and at the same distance from one another and the lower part 23 can consist of angle irons welded together in the region of the corners specified by the rods 24 and the The angular iron polygon can be aligned horizontally by means of height-adjustable screw bolts 25 at the respective corners. The rods 24 are with the lower part 23 by insertion the same in suitable socket holes along said angle iron and locking, for example by screw fastening, rigidly connected and the upper part 22 corresponds essentially to that of the lower part 23 in its embodiment, so it can in turn be made of angle iron, additional struts 26 holding a central axle bearing 27, which is fixed twice in this way, i.e. at its upper and lower ends. In the central axle bearing 27, an axle shaft 9 is inserted, which projects beyond the upper part 22 in the manner shown in FIGS. 7 and 8. The corner regions of the upper part 22, like those of the lower part 23, are provided with continuous vertical bushings and corresponding bores, which specify slide bearings for the rods 24. A height adjustment of the upper part 22 on the central section of the supporting lower part 23 can be carried out over the entire length of the rods 24, a continuous fixation by means of suitable screw locks being possible. Instead of the height-adjustable feet 25, which can be provided in the exemplary embodiment at all six corners or advantageously only at three corners of the substructure, it is also possible to attach mobile rollers or wheels in order not only to be able to adjust the axle bracket 21 in the horizontal direction but also if necessary also bring it into any angular position to a vertical cutting plane. On the upper free end with the axle shaft 9, the center line of which coincides with the vertical center axis 8 of the container, one or more sockets can be plugged on, which are connected to connectors, for example by welding, to which in turn the swivel arms 12 to accommodate the load blocks 14, as described in FIGS. 1 to 6, are to be attached. From FIG. 8 the bores 29 for receiving fixing screws within the bearing bushes 28 of the upper part 22 can be clearly seen, in contrast to FIG. 7 no bushes 30 with associated connecting pieces 31 are placed on the axle shaft 9 here.

As shown in FIG. 9, both the lower part and the upper part are additionally secured with radial struts 32 in addition to the angle irons connecting the bearing bushes 28 to one another, or can at least be secured in this way, in particular the upper part 22 requiring these radial struts 32 in order to secure the central axle bearing 27 , as shown there, to be clearly fixed and secured against possible torques.

Different boiler curvatures can, as in the exemplary embodiment according to FIGS. 1 to 6, be compensated for by adjusting the angle of inclination towards the center. Different axis lengths can be taken into account in the simplest way when the tank arms are correspondingly different by suitable extension on the swivel arms 12. In this context, mention should also be made of the fact that it is possible to design the swivel arms 12 telescopically, so that their length can be set as desired. A length-adjustable connecting piece, not shown here, serves as an end piece for balancing the center point and the load frame, a plate, for example a steel plate, with corresponding bores and a corresponding counter plate that can be tilted, in turn, can adjust the angle of inclination of the swivel arm continuously and practically as desired.

Claims (8)

1. Device for the maintenance of large containers, such as storage tanks and vessels of this type, preferably of at least approximately circular cross-section, comprising a frame structure for the accommodation of a plurality of work platforms along the container wall, which is mounted to be pivotable around the axis of symmetry (8) of the large container along its entire peripheral surface whilst being supported at least in the area of the upper container edge, and a plurality of radially outwardly extending pivot arms (12), to the respective free end, which protrudes over the container wall, are fitted guiding grids (20̸), characterised in that the pivot arms (12) are hinged with their respective inner end to an adjustable central bogie (1) or axial box (21).
2. Device according to claim 1, characterised in that the bogie (1) is arranged to be horizontally and perpendicularly adjustable around a ventilation dome (2) of the container roof (4).
3. Device according to claim 2, characterised in that the bogie (1) comprises a flange bushing (11) and a frame (17), and that horizontally adjustable running wheels (15) are received by the flange bushing (11), and perpendicularly adjustable rollers (18) are received by the frame (17).
4. Device according to claim 3, characterised in that additional holding means (40) for the pivot arms (12) are attached to the frame.
5. Device according to claim 1, characterised in that the axial box (21) is positioned centrally on the container roof (4), comprising a top section (22) and a bottom section (23), in which respect the bottom section has threaded bolts (25) to facilitate horizontal setting of the axial box (21) on the container roof, and the top section (22) receives an axial shaft (9) which is aligned centrally to the perpendicular central axis (8), on which are mounted, via push-on bushes (30̸), connecting pieces (31) for holding the pivot arms (12).
6. Device according to claim 5, characterised in that the top section (22) of the axial box (21) is height adjustable relative to its bottom section (23) by means of rods (24).
7. Device according to one of claims 1 to 6, characterised in that the pivot arms (12) are supported in the area of the upper container edge (7) of the storage tank (3) by means of load trusses (14).
8. Device according to one of claims 1 to 7, characterised in that the pivot arms (12) are held at specified angular distances therebetween by means of connecting webs (5).

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