DE3024031A1 - Underground water reservoir for heat pump - has foam insulating layer inside concrete layer with embedded heat exchange coil - Google Patents

Abstract

The underground water reservoir is for direct connection to a heat pump or may be used with a solar heating system. It carries an insulating layer of a rigid foam material. This is in turn protected by a load bearing layer of e.g. concrete in which are embedded the coils of a heat exchanger. The tank forming the reservoir is filled with water or other liquid and protected against frost by having in the water bodies filled with a liquid which can be solidified, more easily than water. The tank can be mounted horizontally or vertically.

Description

PATENT LAWYERS

DR.-ING. R. DÖRING _ 3. DIPL.-PHYS. DR. J. FRICKE

BRAUNSCHWEIG MUNICH

Ludwig Reitmaier KG, 8261 Marktl

"Feed water tank designed as an underground tank for heat pumps"

The invention relates to a feed water tank designed as an underground tank for heat pumps, where the outside of the tank is covered with a layer of heat-insulating material, such as rigid foam or the like., and on this at least one layer of flowable elements, especially coils of pipes or hoses, is applied, which is enclosed by a jacket made of mechanically resistant material, especially concrete flow-through elements are arranged in terms of flow between the return of the heat pump and the tank inlet.

It is known that in heating systems with a heat pump, the feed water of the heat pump is used for heating via a heat-absorbing circuit to lead, with the warmed up water to increase the heat capacity and heating duration in a feed water tank from which the heat pump can draw in the feed water if required. To reduce the water consumption is the return water from the heat pump is routed through the heat-absorbing circuit for reheating. The heat absorbing one The circle can be of various types. This can be the case here

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be a sensor fed by solar energy. The heat absorption circuit can also waste heat from existing Systems or geothermal energy through a pipe system laid in the ground.

It is also known to connect several heat-absorbing circuits of different types to a heat pump, so as to create a larger one To have independence from additional heating sources.

The heat-absorbing systems arranged in the ground are largely independent of the weather and geographic location provide the required energy at all times when properly laid and expanded. However, such heat-absorbing systems can Can only be used in unused areas or in new systems without too much effort, as the large-area laying In the case of areas that have already been used, considerable effort is required to repair the damage caused during laying.

You therefore already have a feed water tank for heat pumps proposed, which is designed as an underground tank, with a layer of on the heat-insulating layer of the underground tank a fluid through which elements are arranged. The situation for its part in a jacket made of mechanically resistant Material encased with good thermal conductivity. This is preferably concrete. The fluid flowed through Elements of the layer is connected in terms of flow between the return of the heat pump and the feed water tank. This arrangement is particularly suitable for subsequent installation, especially in hybrid systems in which an additional

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additional heat-absorbing system, such as solar cells or the like, is connected to the heat pump. Particularly suitable is such a system in underground tanks in which a large part of the volume of the feed water tank with hermetically sealed Individual containers, for example in spherical shape, are filled. The remaining volume of the tank is covered by an antifreeze freeze-protected feed water is filled, while the individual tanks contain a non-frost-protected liquid, like water, so that especially the heat released when water freezes is dissipated to the heat pump can be.

Compared to the laying of a widely branched area system of pipelines, such an underground tank requires only a small amount Installation space, so that a subsequent installation in used terrain such as gardens or the like. Mostly possible without difficulty is. However, the heat absorption from the ground is limited compared to a surface system. The installation of such a tank to such a depth that the tank itself rests in the groundwater, usually requires such large and deep construction pits that the advantage the small installation space is largely lost compared to flat heat absorption systems.

It is the object of the invention to remedy this and to develop this not previously known older proposal so that the Effectiveness as well as the installation of the Spexse water tank can be done much more easily and space-saving and yet

Sufficient heat contact with the return of the heat pump connected flow-through elements with the ground

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is guaranteed to heat the return fluid so far that the liquid in the tank or in the closed container arranged in the tank after it has frozen Fluids returned to the liquid state.

This object is achieved in that the elongated tank is arranged upright and at its lower end with a from the tank bottom protruding base is provided, and that the position of the flow elements also over the larger Part of the height of the stand is sufficient. Several advantages are achieved in this way. For one, the tank can be a big one Have length without the surface dimensions of the excavation pit required for this being particularly large. In addition, the overall length these installation units are extended by the base so far that at least the base area of the underground tank comes to lie in the range of the normal groundwater level. Since now the position of the flowed through elements, which is connected to the return of the heat pump, with the pipe or line windings wound into the foot area can be, one thereby obtains an overall greater length of the flow elements serving to absorb heat, because in addition to the turns wound around the circumference of the tank, there are also numerous turns at the level of the foot section to be added. This also ensures that even if the tank as such is not in the groundwater area is enough, but the heat-absorbing elements flowing through from the ground are flowed against by the groundwater can, so that a high heat absorption through the flowed through elements is possible even in tight spaces. Since usually that

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Groundwater, even if it is sometimes weak, can flow through the groundwater through the heat-absorbing pipe elements Sufficient heat can always be supplied to ensure that the temperature inside the tank drops below freezing point ensure that the tank contents are warmed up to temperatures above freezing point. Another major benefit lies in the fact that the total weight of the tank and the contents of the tank are now on the solid ground via the stand the excavation can be supported so that the weight is no longer over the thermal insulation, the layer wound on it and the concrete shell must be removed. This results in a much greater security against damage to Parts of the unit.

With the upright arrangement, the tank can be raised above the height of the feed water tank, but especially in the foot area in the Make the diameter decreasing, which facilitates the installation of the excavation-free installation of the excavation even at great depths and ensures that the excavation pit only covers an appropriately small area on the surface of the ground needs to own.

If the flowed through elements of the layer consist of a material, It is the fact that no changes, especially damage, can be expected over many years of use in the groundwater area It is advantageous if the flowed-through elements are exposed, i.e. without a jacket made of mechanically resistant material, at least in the foot area Material in order to achieve the best possible heat transfer from the groundwater to the

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retaining fluid. But it is also quite beneficial and it is also possible to embed the turns in the area of the foot section in a concrete jacket or the like. Here is however, the arrangement is advantageously made so that the entire foot section has several openings in such an arrangement has that the jacket can be freely flowed through by the groundwater. It is useful when installing on it ensure that the openings are arranged in the general direction of flow of the groundwater.

In the foot section of the structural unit, the flow through elements can also be designed differently in terms of material and shape than the flowed through elements in the jacket area of the feed water tank itself. This makes it possible to flow through Container once in relation to the inflow of groundwater, for to train others in an optimal way with regard to accommodation in the foot area.

The invention is explained below with reference to a schematic drawing explained in more detail using an exemplary embodiment.

The figure shows a vertical section through a feed water tank designed as an underground tank according to the invention.

The entire structural unit, as it can be lowered into a construction pit when it is fully assembled, is denoted by 1. Of the actual feed water tank 2 can be made of metal or plastic and is elongated in the example shown Cylinder formed, which is arranged upright,

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is closed at the bottom and on the upward-facing face has an opening that is permanently closed after completion, to which the individual lines and fittings that are used for the circuit control are necessary, are connected. These are not shown. Only the return line 11 is indicated for the return line 7> connected to the heat pump through which the fluid cooled in the heat pump runs back into the interior of the feed water tank 2. The feed water tank 2 is advantageously with not shown, individual, spherical, Hermetically sealed containers filled in which a freezing and at the temperatures in question thawing liquid, especially water, is filled. Against it the return fluid of the heat pump is a refrigerant or a liquid with "an anti-freeze agent".

The feed water tank 2 is provided with thermal insulation 3, e.g. a hard foam layer, on all sides, i.e. also in the lid area Covered to provide heat insulation to the outside.

A foot section of noticeable height is connected to the closed bottom of the Spexse water tank 2, for example the consists of a cylinder A welded to the floor, which in turn at its lower free end into a standing plate 5 transforms.

On the hard show layer 3 of the feed water tank 2 is the Line 7 coming from the heat pump> the line made of metal or plastic may exist, wound with relatively tight turns 8.

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This winding layer extends over the entire height of the feed water tank 2 and continues in the area of the foot section in the form of a tight turn packing 9, which is preferably the entire remaining free space above the plate 5 and around the cylindrical section 4 of the foot. The end of line 7, 8 is led back upwards with a few turns 10 of great incline and connected to the return line 11 of the tank. The height of the base 6 is depending on the installation depth 14 of the top of the unit 1 below the surface and depending dimensioned from the height 15 of the actual feedwater tank 2 so that when installed in a construction pit at least the Foot area 6 protrudes into the groundwater. The soil layer bearing the unit 1 is denoted by 17.

The pipe layers 8 are above the height of the feed water tank 2 and 10 embedded in a jacket made of mechanically resistant material, in particular concrete. The jacket is denoted by 5. If the material used for the pipelines 9 is sufficiently resistant to the influences even with long installation times are in the ground, especially in the groundwater, the pipelines 9 can be arranged so as to be exposed in the foot area, see above that they protrude freely into the groundwater. A mechanical stress on these lines 9 is not to be feared, since these are arranged protected between the resistant parts of the concrete jacket 25 and the plate 5 of the foot section 6. It however, it is also advisable to embed the lines 9 in the base section 6 in the resistant material, such as concrete 25. In In this case, however, it is advantageous if windows or channels 12 are provided in the foot section, which have a central

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Opening 13 of the foot section are in communication, so that the groundwater, which mostly shows a flow movement, the Can flow freely through the foot section or the channels 12. This creates a very intensive heat exchange between the groundwater and the fluid in the lines 9 guaranteed. At the same time, the load-bearing part 4.5 of the foot section is through the concrete casing largely protected against the effects of groundwater.

Instead of the pipelines 9, other lines through which the fluid can flow can also be used Chambers or channels or the like. Be provided in the foot section to which the lines 8 and 10 are connected accordingly are.

In the example shown, only the foot section 6 is designed to taper conically downwards so that it can be inserted into an excavation to facilitate great depth but not too large a cross-section in the area of the top of the earth. The arrangement can, however, be advantageous also be designed so that the feed water tank 2 is not cylindrical, but frustoconical and is tapered downwards so as to have a relatively small diameter of the base of the excavation to be able to get by. This makes installation much easier.

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Claims (5)

PATENT LAWYERS 5507 302A031 DR.-ING. R. DÖRING DIPL.-PHYS. DR. J. FRICKE BRAUNSCHWEIG MUNICH Claims ( 1 J A feed water tank designed as an underground tank for heat pumps, in which the outside of the tank is provided with a layer of heat-insulating material, such as rigid foam or the like is enclosed by a jacket made of mechanically resistant material, especially concrete, with .die flowable elements are arranged in terms of flow between the return of the heat pump and the tank inlet, characterized in that the elongated tank (2) is arranged upright and at its lower end with a stand (4,5) projecting downward from the tank bottom, and that the position of the elements (8) which can be flown through extends over the greater part of the height 16 of the stand (4,5). 2. Feed water tank according to claim 1, characterized in that the stand (6) for a through-flow Is formed perforated by groundwater or the like. 3. Feed water tank according to claim 2, characterized in that the pipe or hose forming the layer bundles (8,9,10) in the foot section can flow freely from the outside 1 * 006 * 10311 - 2 are arranged. 4. feed water tank according to claim 1 or 2, characterized in that the or each layer of can flow Elements also in the foot section in a jacket made of mechanically resistant material such as concrete, are embedded, the openings (12,13) for the flow of the groundwater. 5. Feed water tank according to one or more of the claims 1 to 4, characterized in that the flow through Elements returned from the foot section (6) in the jacket (5) to the ceiling section (3) and there are connected to the tank inlet (11). 130062/03It