DE2420628A1 - Thin-walled externally-supported pressure vessel - for nuclear use, with support construction outside vessel insulation - Google Patents

Abstract

Container, having a sealed inner vessel surrounded by an insulating layer, esp. a pressure vessel for nuclear purposes, capable of being dismantled, has an inner vessel constructed as a sealing skin, while a mesh-type support construction with bottom and top sections is provided outside the insulating layer. The inner vessel incorporates expansion membranes or corrugations both longitudinally and transversely.

Description

Container The invention relates to a container with a sealed inner container and an insulating layer surrounding the inner container, in particular one that can be dismantled Pressure vessels for nuclear purposes.

Concrete containers with an internal liner are known.

These containers have the disadvantage that the load-bearing components are inside the insulating layer are arranged so that they keep the temperature of the in the container Accept goodness. The load-bearing components are subject to rapid aging.

In addition, the necessary container size is constantly growing, so an efficient workshop production can be replaced by an expensive assembly production got to.

The invention avoids the disadvantages mentioned and also allows their use as a burst protection for known containers.

The invention has the following advantages: 1.) The support structure or the burst protection is constantly accessible and can therefore be checked at any time.

2.) Parts of the supporting structure or the burst protection are exchangeable, so that repairs can be carried out at short notice during a shutdown can.

3-.) The supporting structure or burst protection is outside the Insulation and therefore only has the temperature of the surrounding room, so accelerated aging processes due to high temperatures can be avoided. the Ring Constitution ls1 very a; if dissolved and can therefore be completely covered by the ventilation.

4.) The dismantling of the supporting structure and / or the burst protection allows repeat exams.

5.) The supporting structure is also designed as a burst protection.

The present invention is characterized in that the inner container is designed as a sealing skin and that outside the insulating layer a reticulated Supporting structure with floor and roof parts is arranged in particular on the inner container Stretched membrane arranged both in the longitudinal direction and transversely to the longitudinal direction or waves provided. The inner container is preferably in the insulating layer anchored and the insulating layer is by extending in the longitudinal direction of the container Supports pilaster strips that are anchored in the floor and roof structures. According to Another idea of the invention is that the irises are preferably outside the insulating layer arranged tensioning elements connected to each other.

The invention is shown in FIGS. 1 to 5 by way of example and schematically shown.

Fig. 1 shows an elevation of a container.

FIG. 2 shows a section along the section line II in FIG.

Fig. 3 shows a detail of the container.

4 and 5 show in detail a tubular passage through the reticulated structure in elevation and floor plan.

Fig. 6 shows the design of a burst protection in plan.

In Fig. 1, a container is shown in an elevation, the one embodied as a sealing skin inner container 6, the one made of prefabricated parts existing insulating layer 4 and an outer network-shaped supporting structure is surrounded. The inner container consists of cylindrical wall parts 19, conical roof structures 20 as well as from a circular floor construction 21. These construction elements 19-21 are connected to one another by expansion membranes 9. This expansion membrane 9 are not only perpendicular to the container axis 22, but also parallel to it, like it shown in Fig. 2 is arranged This measure allows the container made of relatively small components that were manufactured in the workshop, can be easily assembled at the assembly point. Furthermore, the container is a result this construction is very elastic, so that in the wall of the inner container 6 no significant tensions occur.

As can be seen in detail from FIG. 3, the structural elements are 19-21 connected to the insulating layer 4 by anchors 10 and 8. The insulating layer 4 consists of prefabricated components that are separated by expansion joints 5, so that the insulating layer 4 can expand with the inner container 6. The expansion joints 5 are with a joint material filled out. On the back of the expansion joint 9 is the space between the insulating stones and the membrane is sealed by a backfill 11.

The tensions that occur due to the internal pressure are through an outer reticulated structure was added. Are in the circumferential direction of the Container clamping elements 7 are provided in vertical parallel to the container axis 22 running pilaster strips 1 are mounted. The clamping elements, e.g.

Prestressing steels, run along straight lines and form a polygon, whose corner points are formed by the pilaster strips 1. The pilaster strips 1 are at their ends held in a construction that forms the floor and roof structures 2 and 2a In this construction, in particular in the roof construction 2a, there is an opening 18 provided, which is designed as an entry 3 for the container. This soil and Roof structures 2 and 2a are advantageously formed by planar structures that if necessary, are poured with concrete to form a composite structure.

The concrete and roof structures 2 and 2a are supported by tendons, such as ropes, connected to each other. These tendons can also be used as tendons be trained.

In Figs. 4 and 5, a radial passage is in two cracks, in particular a pipe leadthrough is shown. This implementation is by one Tube 13 is formed, which allows passage 17. On the outside of the passage 17, an annular support structure 13 is provided, which Powers the clamping element 7 closes the passage over the passage. On the inside of the container is connected to the tube 12 of the inner container 6; On the outside of the waves of the Inner container 6 expansion and drainage joints 14 are provided so that the Inner container 6 can also stretch between two anchorages 8. The tightness of the Container, in particular the inner container 6, can through the drainage joints 14 must be checked continuously, even during operation. This is the danger of a sudden rupture.

The pilaster strips 1 are formed, for example, from composite beams that have 4 steel longitudinal webs 16 on their bearing surfaces on the insulation, which are connected to the concrete by not shown. At the clamping points the clamping elements 7 are for the transmission of the ring forces longitudinal lamellae 15 on the Provided for the outside of the pilaster strips. The clamping devices for the clamping elements 7 are indicated in FIG. 2 by crosses at the ends of the clamping elements 7.

As can be seen from Fig. 3, the inner container 6 is a welded construction. Of course, screw constructions can also be used in place of the weld seams so that the container is even easier to dismantle.

However, the container construction is not based on containers with a load-bearing external net construction, but also includes a burst protection for pressure vessels that exist in terms of strength even without the net construction can, so that the burst protection or break protection can also be applied subsequently can be.

In Fig. 6 is a part of a container in plan with an outer one Break or burst protection shown. The container consists of a tight inner container 6, which is surrounded by an insulating layer 4. In the insulating layer 6 is a ring-shaped supporting structure provided for the container stresses, which is made up of tendons 23 is formed, which surround the inner container 6 in a polygonal manner. Except for Insulating layer 4 is provided similarly to the bursting device in FIG. 2, which is shown in FIG in this case is relieved of the static tank tensions. The burst protection again comprises pilaster strips 1 and tensioning elements 7.

Claims (16)

PARITANSPt; CHE: 1. Container with a tight inner container and an inner container surrounding insulating layer, in particular dismountable pressure vessels for nuclear Purposes, characterized in that the inner container (6) is designed as a sealing skin and that outside the insulating layer (4) a reticulated structure with floor and roof parts (2, 2a) is arranged. 2. Container according to claim 1, characterized in that the inner container (6) stretching membranes (9) arranged both in the longitudinal direction and transversely to the longitudinal direction or shafts are provided (Fig. 1S2) o 3. Container according to claim 1 or 2, characterized characterized in that the inner container (6) is anchored in the insulating layer (4) and the insulating layer (4) by pilaster strips running in the longitudinal direction of the container (1) is supported, which are anchored in the floor and roof constructions (22 2a) (Fig. 2,3). 4. Container according to claim 3, characterized in that the pilaster strips (1) are connected to one another by clamping elements (7) (Fig. 2). 5. Container according to claim 4, characterized in that the clamping elements (7) are arranged outside the insulating layer (4) (Fig. 2). 6. Container according to claim 3, characterized in that the pilaster strips (1) Longitudinal lamellae (15) for absorbing the ring forces of the clamping elements (7), transverse ones Bars and pressure distributing long bars16) include? which the tension forces transferred to the insulating layer (4) and thus support the inner container (6) (Fig. 2). 7. Container according to claim 3 or 6, characterized9 that the insulating layer (4) on the pilaster strips (1), in particular their longitudinal webs (16), Can be moved to accommodate changes in length as a result of heat and loads is arranged. 8. Container according to claim 1 or 3, characterized9 that the floor or roof structures (2 2a) are designed as surface structures, at least one sheet-metal structure being designed as a ring-shaped hollow box, through which the inner container (6) is accessible through an opening (18) (Fig. 1) 9. Container according to claim 8, characterized in that the planar support structures are filled with concrete. 10. Container according to claim 1 or 8, characterized in that the floor and roof structures (2, 2a) by tendons, e.g. Ropes, in particular pre-tensioning members such as pre-stressing steels, with one another are connected. 11. Container according to claim 8 or 9, characterized in that the surface structures (2) of developable surfaces, such as prismatic cladding or cylinder and conical surfaces are limited. 12. Container according to claim 4, characterized in that the clamping elements (7) locally through a passage (17) permitting frame (13) are interrupted for the implementation of pipes in which the clamping elements (7) are anchored on both sides (Fig.4,5). 13. Container according to claim 1 or 3, characterized in that the inner container (6) together with the insulating layer (4) forms a pressure vessel, wherein the outer reticulated structure as a break or. Anti-burst device trained is. 14. Container according to claim 13, characterized in that inder Insulating layer (4) both in the circumferential direction and in the longitudinal direction of the tendons are provided that absorb the static tank tensions (Fig. 6). 15. Container according to claim 1 or 13, characterized in that the insulating layer (4) as a prefabricated structure with arranged between the prefabricated parts Expansion joints (5) is formed (Fig. 1 and 2). 16. Container according to claim 1 or 2, characterized in that the inner container (6) consists of wall parts that are connected to one another by expansion membranes (9) are connected.