EP0067428A1 - Pressureless large tank for the storage of hot water - Google Patents

Abstract

Utilisation of the volume of a large tank for the storage of hot water having a floating lid (7) is improved according to the invention by an elastic bridging of the connection point between the tank bottom (1) and the lower edge of the side wall (2) with the aid of an elastic element (3), such as, in particular, a semitube, which allows direct connection of the lower load-changing device to the base plate. Furthermore, the edge of the floating lid (7) is preferably extended by an upwardly projecting hoop (6) and a downwardly protruding collar (5), and the gap between the lid and the side wall is filled by a sealing liquid (8) which floats on water and is covered, in particular, by a layer (9) of grains made of a lightweight insulating material for heat insulation. In an arrangement of this type, the upper load-changing device can be connected directly to the floating lid. The elastic bridging according to the invention can also be used generally for heated liquid containers, in which the base and side wall are produced separately. <IMAGE>

Description

The invention relates to a pressureless large tank for hot water storage with a floating lid and with an upper hot water inlet and outlet and a lower cold water inlet and outlet.

In district heating systems based on cogeneration, heating water tanks have been used for a long time, for example to decouple the generation of electricity and heat and to cover peak heat requirements. However, the accumulators in operation in Germany are for pressures that are significantly higher than the. Ambient pressure, designed and therefore subject to tight limits in terms of volume but also for cost reasons. Only recently has the knowledge gained acceptance that so-called "unpressurized" hot water tanks in the form of large cylinder tanks, such as have been in use in the mineral oil industry for a long time, can be used much more economically as heat stores than pressure tanks (batteries). The first containers of this type with maximum volumes up to 30 00 ₀ m have been in operation in Sweden for several years and a first one is also under construction in the Federal Republic.

These stores have been more or less taken directly from oil storage technology. They have a fixed roof, which due to the large dimensions (currently up to 42 m diameter) can only be designed for very low negative and positive pressures. With regard to changes in temperature and level, this requires very complicated, sensitive pressure control and complex safety measures. The lower flat bottom can be made of very thin sheet metal, whereas the lowest cylindrical section must have a considerably thicker wall, since it has to absorb the greatest circumferential stresses from the hydrostatic pressure of the liquid column. Welding these different sheet thicknesses is possible and also sufficient for oil tanks that are not subject to any significant temperature fluctuations. For heat storage devices that are inevitably subject to relatively large and rapid temperature changes in the heating water, this welded joint is to be assessed much more critically. So far, it has been helped that the bottom has been reinforced at the edge, which is relatively expensive, and that the thermal expansion stresses have been reduced by not having to replace the lower (always cold) water layer during charge changes. However, this leads to a significant loss in the volume usage of the memory. A further reduction in volume use was also accepted in the vicinity of the fluctuating water level, in that the load changing device which had to float for this purpose had to be at least 0.5-1 m below the water level with the upper edge in order to avoid the suction of air or vapors .

The aim of the invention is therefore a better utilization of the tank volume, in particular by ensuring that the bottom of the container is relieved that the cold water supply and discharge can take place immediately above it, and furthermore means are provided which the hot water supply and discharge directly below the Allow cover.

The pressureless large tank for hot water storage of the type mentioned initially developed for this purpose is essentially characterized by an elastic bridging of the connection point between the tank bottom and the lower edge of the side wall by means of an elastic component connected to both elements, in particular in the form of a half pipe .

Further special features of the invention emerge from the claims and the following description.

• Figur 1: einen Vertikalschnitt durch einen Großtank;
• Figur 2: den unteren Anschluß des Behälterbodens an die Seitenwand in vergrößertem Maßstab und
• Figur 3: den Bereich zwischen Deckelrand und Seitenwand, ebenfalls in vergrößertem Maßstab.

The invention will be better understood in particular on the basis of the explanation of an exemplary embodiment which refers to the attached drawings; it shows schematically:

• Figure 1: a vertical section through a large tank;
• Figure 2: the lower connection of the container bottom to the side wall on an enlarged scale and
• Figure 3: the area between the lid edge and side wall, also on an enlarged scale.

The large tank shown in the diagram in FIG. 1 has, as shown in more detail in FIG. 2, to relieve the connection point between the tank bottom and the side wall an elastic element 3 (for example half-tube, U-tube, angled or profiled tech) welded to the container bottom 1 and the side wall 2, which is welded in particular to a flange ring 4 which is welded and supported on the lower edge of the side wall 2.

In this way, the critical weld connection between the thin tank bottom and the thick lower cylinder section is relieved by a circumferential elastic component. This allows the tank bottom and jacket to expand radially to different extents, and different temperatures during charge changes between the bottom (e.g. 50 ° C) (e.g. 950C) and jacket are reduced by heat conduction via this elastic link. In addition, this component can also compensate for slightly different vertical settlements between the ring foundation for the cylinder jacket and the foundation - as far as this is still necessary - under the tank floor, which is significantly less statically loaded.

This relief makes it possible to connect the lower load changing device directly to the floor panel, which leads to savings in construction costs and to better volume utilization.

As shown in FIG. 3, the tank top is designed to be floating, a collar 5 projecting downwards and a hoop 6 projecting upwards having an associated ring pontoon 6 'being provided on the edge of the lid 7. The gap formed between the cover 7 and the side wall 2 is at least so wide that the differences in expansion which may occur due to different heating effects are absorbed. It absorbs the sealing liquid 8 which is covered in particular by a grain layer 9 which has a substantially heat-insulating effect.

A floating cover of a hot water tank is already known from DE-OS 2 049 574, which is, however, formed by elastic cushions provided with insulation, the thickness of which is sufficient to hold a sealing filling medium such as paraffin in the gap formed towards the side wall.

According to the present concept, the blanket is formed by a floating cover, to which the upper loading change device can be connected directly and which is connected to a downwardly projecting collar and upwardly projecting hoop. The insulating liquid provided in the gap, such as paraffin, should have a layer height of at least 100 mm, and it is preferably covered with grains of a light, temperature-resistant insulating material, such as Ca 100 mm polyurethane foam or Perlit0. The collar protruding downwards ensures that the light liquid is not sucked into the heating water when the load is changed. The thickness of the layer makes it unnecessary to monitor the height of the layer meticulously.

Another advantage of this liquid layer, which is compatible with steel, is that a film of this liquid prevents the build-up of rust during temporary water level drops and the liquid has a good lubricating effect. Due to the floating roof construction, the above-mentioned complex is eliminated Differential pressure control. This becomes particularly expensive if no steam is available at the installation site to maintain a steam cushion and the storage contents have a temperature that is significantly below 100 ^° C., ie if the storage is thermally discharged.

The prevention of air access into the storage water achieved with this construction allows the connection of the upper charge changing device directly to the floating ceiling. As a result, this can be carried out considerably more simply, since its upper plate is identical to the ceiling plate and a separate floating device is unnecessary. In addition, it is ensured that the hot water can always be fed in or sucked off at the top, so that a correspondingly better use of the volume of the valuable storage space is possible.

The relief in the connection point between the tank bottom and the side wall, which has been specially developed for the hot water tank, is of course usable for other hot liquid tanks.

Claims (7)

1. Pressureless large tank for hot water storage with a floating lid and with an upper hot water inlet and outlet and a lower cold water inlet and outlet, characterized by an elastic bridging of the connection point between the tank bottom (1) and the lower edge of the side wall (2) by means of an elastic component (3) connected to both elements (1, 2), in particular in the form of a half tube. 2. Large tank according to claim 1, characterized by a flange ring (4) welded to the lower edge of the side wall (2), with which the elastic element (3) welded on the other side to the base plate (1) is welded. 3. Large tank according to claim 1 or 2, characterized by a downwardly projecting collar (5) and an upwardly projecting hoop (6) on the edge of the lid and at least 100 mm high filling of the gap between the side wall (2) and lid (7) with a liquid which is immiscible with hot water, is not corrosive to steel, is lighter and has a higher boiling point (8) than water. 4. Large tank according to claim 3, characterized by an overlaying of the liquid layer (8) with a layer (9) of grains made of a light temperature-resistant insulating material. 5. Large tank according to claim 3 or 4, characterized in that the upper hot water inlet and outlet is connected directly to the floating ceiling. 6. _G ro tank according to one of claims 1 to 5, characterized in that the lower cold water inlet and outlet is connected directly to the bottom plate (1). 7. Warm liquid container, in which the base and side wall are made separately, characterized by an elastic bridging of the connection point between the container base (1) and side wall (2) according to one of claims 1 or 2.

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