DE102011108821A1 - Filling material, useful e.g. for underground cable, comprises three materials, where first material is base material, preferably cement and/or bentonite, second material is heat-conducting particle, and third material is displacer - Google Patents

Abstract

Filling material for a ground-coupled heat exchanger and underground cable, comprises at least three materials, where the first material is a base material, preferably cement and/or bentonite, the second material has a thermal conductivity of less than 1 W/mK, and the third material is a displacer, which is impermeable to the second material. Independent claims are included for producing the filling material comprising combining the base material and the displacer, preferably infiltrating the base material into the displacer and producing a composite with the second material, which is a heat-conducting particle, or combining the second material, which is the heat-conducting particle, and the displacer and subsequently combining with the base material, preferably infiltrating the base material into the obtained composite.

Description

The invention relates to a method for improving multi-component functional materials with a transport process as an essential function. The use of displacement bodies reduces the space available for the functional particles which are responsible for the transport process so as to achieve a higher density and better coupling of the functional particles, while at the same time forcing a structure of higher functionality.

In particular, the present invention relates to a Bohrlochverfüllmaterial for geothermal probes in which graphite is used as part of the backfill material as a functional component to increase the thermal conductivity and thus to increase the transmission of heat output, and a method for optimizing the heat and mass transfer in these materials and their application.

[State of the art]

In solids, various transport processes take place: heat transport (thermal energy), electricity (electrical energy), radiation (electromagnetic energy) or mass transfer (mass). For a variety of reasons, it may be necessary to reduce the amount of solid or the amount of transport particles, which are responsible for the transport process. In the simplest case, the solid body consists only of transport particles, in the extended case, the solid body consists of different particles, in which case only those particles are relevant, take over a function, d. H. require a transport process. These are referred to below as transport particles. In use, there are often conflicting or very different demands on materials, such as heat storage and rapid heat dissipation or, for example, stability and porosity.

The problem is often to optimally use the amount of transport particles used, and to be able to use any space available for other desirable functions, to save material or to improve the functioning of the transport particles.

• 1. die Transportteilchen in direktem Kontakt stehen (Überschreiten der Perkolationsschwelle)
• 2. die Transportteilchen ihrer Form entsprechend optimal ausgerichtet sind, so dass sie in möglichst direktem Kontakt zueinander stehen.
• 3. die Transportteilchen bei vorhandener Anisotropie des Materials aus dem sie bestehen in Bezug auf den Transportvorgang optimal ausgerichtet sind.

It should be noted in particular that the transport process is generally improved when

• 1. the transport particles are in direct contact (exceeding the percolation threshold)
• 2. The transport particles are optimally aligned in their shape, so that they are in direct contact with each other as possible.
• 3. the transport particles are optimally aligned with existing anisotropy of the material from which they exist in relation to the transport process.

For long-term storage of heat energy, the geothermal heat storage is a successfully used variant of geothermal heat pumps. The geothermal probes allow the supply and removal of heat energy in the ground by water or other heat transfer fluid in a closed circuit.

In suitable soil zones, vertical holes are drilled, which are usually more than 10 m in length and about 20 cm in diameter. In these holes suitable water pipes (eg U-pipes or coaxial pipes made of PVC) are used. With a Bohrlochverfüllmaterial made of special concrete, the thermal contact between the geothermal probe and the surrounding soil is ensured and mechanically fixed the pipes.

Usually, mixtures of water, bentonite, cement and quartz sand are used as fillers. The level of heat conductivity of the filling material is decisive for the thermal performance of the geothermal probe.

To increase the thermal conductivity of the Bohrlochverfüllmaterials is in the patent DE 199 29 697 A1 ] the addition of graphite to the wellbore material is recommended. With the compositions specified in the patent, a doubling of the thermal conductivity can be achieved.

OBJECT OF THE INVENTION

The basic idea of this invention is to reduce the available space, which is available for the transport particles that realize the transport process through the use of displacement bodies mentioned hereinafter. By the displacement body, a close contact between the transport particles can be forced, their shape can be optimally aligned, and be achieved with anisotropy optimal alignment. Thus, by exceeding the percolation threshold even at a very low density of transport particles, a decisive jump in the required transport phenomenon is observed. The displacement body can also be a matrix which aligns the transport particles by its structure and thereby also succeeds in exceeding the percolation threshold.

In the simplest embodiment, it is a two-component material consisting from transport particles and displacement body. Here only one transport process is optimized, such as heat transport. Unless a displacement body is found for this material, which at the same time also brings about an additional desired function as properties, for example heat storage.

In further embodiments, the displacement body only serves to structure the transport particles and a further component takes over the second function. Here, on the one hand, the displacement body permeable to the third component, hereinafter referred to as functional material, or be the displacement body is removed after a fixation of the transport particles, for example by adhesive, from the solid, for example by pyrolysis, and then resulting displacement body gaps with a Functional material filled.

Based on this procedure, the most diverse multi-component functional body can be produced. The transport particles take over a transport process - thermally, electrically, optically or materially. The displacement body structures the transport particles and thus optimizes the transport process. At least one additional functional material reinforces the required application properties of the body. This can also be a transport process or a storage process. The functional material can also serve to increase the mechanical stability or optically (absorption, scattering, color impression, thermal radiation, etc.) to improve.

• 1. die Transportteilchen in engem Kontakt stehen (überschreiten der kritischen Dichte = Perkolationsschwelle), das heißt einen durchgängigen Transportpfad bilden
• 2. die Transportteilchen in ihrer Form optimal ausgerichtet sind
• 3. die Transportteilchen bei vorhandener Anisotropie des Materials aus dem sie bestehen in Bezug auf den Transportvorgang optimal ausgerichtet sind.

When using a base material, in which the transport particles are added, further moldability is possible in principle. The distribution of the transport particles in the base material can be targeted or random. It should be noted in particular that the transport process is generally improved when

• 1. the transport particles are in close contact (exceeding the critical density = percolation threshold), ie forming a continuous transport path
• 2. the transport particles are optimally aligned in their shape
• 3. the transport particles are optimally aligned with existing anisotropy of the material from which they exist in relation to the transport process.

In the targeted alignment and spatial arrangement of the transport particles, there are the two limiting cases of parallel connection, which is optimal, and the series connection, which represents the worst solution.

In the targeted orientation of the transport particles, the orientation of the transport particles in the direction to be transported in the optimal direction; A statistical orientation or an orientation rotated by 90 ° does not optimally use the transporting material.

A statistical distribution with respect to their spatial arrangement also does not optimally use the transporting material. A significant increase in the transport process with minimal concentration of the transport particles takes place only at the so-called percolation threshold ( ), at which the necessary critical density of the transport particles is reached to form a continuous transport path through the composite or the base material in which the particles are in contact with each other. At this density, however, without base material / composite there is no mechanical strength.

In is the statistical distribution of transport particles and exceeds the percolation threshold (critical density) at which a continuous transport path (thick lines) is formed.

• – Die Menge der zugeführten Transportteilchen zeigt erst nach Überschreiten der Perkolationsschwelle (kritische Dichte) einen nennenswerten Anstieg des gewünschten Effektes
• – es besteht an der Perkolationsschwelle noch keine mechanische Stabilität, und daher die
• – Gefahr, dass die Transportteilchen in der flüssigen Phase des Basismaterial durch die unterschiedlichen Dichten von Basismaterial und Transportteilchen separieren.

In order for the transport particles to significantly increase the transport process and to ensure stability in a liquid or gaseous base component, they must be available in sufficient density. This results in the following disadvantages:

• - The amount of the supplied transport particles shows only after exceeding the percolation threshold (critical density) a significant increase in the desired effect
• - there is still no mechanical stability at the percolation threshold, and therefore the
• - Risk that the transport particles in the liquid phase of the base material separated by the different densities of base material and transport particles.

Through the use of displacement bodies, both distribution and orientation can be optimized with the same number of transport particles. The displacement bodies can for this purpose have a variety of geometries, such as plates, fibers, spheres, etc. An example shows Figure 2, left with uniform distribution without contact of the particles and without mechanical strength, right with compacted distribution and thus contact of the particles and with mechanical strength ,

The invention is based in particular on the object, the required amount of the functional component, ie the transport particles, to increase the thermal conductivity of the filling material for geothermal probes to reduce. For this purpose, so-called displacement body are used, which limit the volume, which is the transport particles to increase the thermal conductivity available. Suitable materials for the displacement body are, for example, inorganic materials such as glass, recycled waste glass or quartz sand. These can be both porous and non-porous. The particle size of the displacers may be adapted to the mechanical requirements of the filler material and may range from about 0.1 to 1.5 mm.

[Embodiment 1]

The mixture according to the invention consists of about 80 wt .-% of the backfill material, mainly consisting of cement and bentonite, without thermal conductivity increasing component, 15 to 20 wt .-% graphite to increase the thermal conductivity and 2 wt .-% perlite as displacement component, corresponding to a volume fraction of about 14%. Without displacement component, the mixture achieves a thermal conductivity of about 2.4 W / (mK), with displacement component a thermal conductivity of 2.5 W / (mK), but with a simultaneous, significant increase in volume and thus saving on the materials used. In the case of this mixture according to the invention, the proportion of the displacement component is between 0.5 and 5% by weight.

[Embodiment 2]

This mixture according to the invention is identical to Example 1 with the exception that instead of perlite quartz sand is used with a particle size of 0.1 mm to 1.0 mm as a displacement component. Here, the mass fraction of the displacement component is 25% to 55% based on the total mass. The advantage of quartz sand is that it has a high thermal conductivity of about 4 W / (mK), which, in addition to its capacity as a displacement component for the graphite portion, further increases the effective thermal conductivity of the filling material. It is typically achieved with a proportion of 15 wt .-% graphite and 30 to 50 wt .-% silica sand a thermal conductivity of about 2.4 W / (mK) to 3.4 W / (mK).

LIST OF REFERENCE NUMBERS

1

Transportteilchen

2

base material

3

Perkolationspfad

4

displacer

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19929697 A1 [0009]

Claims (7)

Backfill material for geothermal and Erdstromkabel of at least three materials, characterized in that one of the materials is a base material, in particular cement, bentonite or a mixture of both, the second material has a thermal conductivity> 1 W / mK and the third material is a displacement body, the impermeable to the second material. Filling material according to claim 1, characterized in that the displacement bodies are adapted to the mechanical requirements of the base material and in the range of about 0.01 mm to 1.5 mm, preferably between 0.1 mm and 1.5 mm. Filling material according to claim 1 or 2, characterized in that the displacement body made of glass, recycled waste glass, perlite, plastic, organic material or quartz sand. Filling material according to one of claims 1 to 3, characterized in that the second material (transport material) is a graphite or expanded graphite. A method for producing a filling material according to any one of claims 1 to 4, characterized in that first the base material and the displacement body are combined, in particular the base material is infiltrated into the displacement body, and then the composite with the second material, the Wärmeleitpartikeln is prepared. A method of producing a composite according to any one of claims 1 to 4, characterized in that first the second material, the Wärmeleitpartikel, and the displacement body are combined and then the composite is made with the base material, in particular the base material is infiltrated into the resulting composite. Use of a composite according to any one of claims 1 to 4 for filling boreholes of geothermal heat exchangers and earth power cables.

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