SE463623B - LATENT HEATER CUMULATOR WITH NON-SOIL MOLDING SUBSTANCES - Google Patents

Description

465 623: 2 disadvantages: - Charging or discharging the accumulator is associated with an increase or decrease of the accumulator temperature, which results in a constant - in practice very disadvantageous - sliding of the accumulator temperature and the heat transfer effect when charging and discharging. , which must be used.

Due to the generally low specific heat capacity of the accumulator materials, the mass / power ratio is very unfavorable compared to the latent heat accumulator described below.

The accumulation of large amounts of heat is associated with large accumulator volumes, which in the technology can often not be realized or can only be realized at high cost (construction of complementary surrounding houses) or which affect the cost conditions very unfavorably.

In order to reduce the accumulator volumes to technically manageable orders of magnitude, large temperature differences between charging and discharging conditions must be allowed and the necessary increase of the charging temperature in addition to the required discharge temperature of the heat consumer system and the deterioration or deterioration of the energy quality. .

When using water, as the most commonly used accumulator material, the accumulation of large amounts of energy becomes particularly problematic when the accumulator temperature required for technical use is at the upper temperature limit for water (depressurized at about 90 ° C), such as for heating systems 90/70 ° C. of the water temperature is not possible without pressure and leads An increase in the capacity to accumulate by increasing to a considerable technical and apparatus additional cost, which further worsens the inherently disadvantageous cost conditions 463 623.

An opportunity to overcome these disadvantages is offered by accumulators which operate less on the basis of sensible heat but more on the basis of latent heat, such as melting and solidifying heat, evaporation and condensation heat, reaction heat, hydration heat, solution heat, crystallization heat and the like. nande.

Accumulators of this type are referred to in the literature as "latent heat accumulators".

Compared with conventional accumulators, these accumulators have the following advantages: - When charging and discharging, the accumulator temperature remains constant within a narrow range during heat absorption and heat dissipation.

- Depending on the technical solution in question, the heat transfer effect also remains constant within a narrow range.

- Compared with conventional accumulators, the heat absorption capacity depending on the accumulator material used and depending on the width of the total temperature range, within which the heat absorption and heat dissipation takes place, is between 2 and 40 times greater.

The most noticeable improvements are in particular such latent heat accumulators, which operate on the basis of the heat of melting and solidification.

For such accumulators, there are a number of solutions which essentially overcome the thermophysical and physico-chemical problems inherent in fusible materials.

These include DE 26 48 678, DD 154 125, DE-OS 19 28 694, 465 625 4 DE-OS 25 23 234, DE-OS 25 17 920 and DE-OS 25 17 921 and WP C 09 K / 24 36 19, which have indicated improvements in the material preparation of the accumulator materials, prevention of subcooling, layering and the like. The following problems have not yet been solved: The tendency of certain non-decomposing melts, such as congruent and eutectic melting materials, to grow from the crystals formed during solidification to agglomerates with large volumes, which in both heat input and heat output lead to greatly reduced heat transfer. effects as well as to crust formation, impermeability to melting, to thermal stresses and increased pressures in the interior of the accumulator.

In addition, it is known from the literature that by the addition of fluorine-containing surfactants the size of those upon solidification of 2804. 10 H 2 O) formed crystals can be reduced. A corresponding patent exists with US 4,267,879 incongruent melting glauber salt (Na. Concrete solutions for reducing the crystal size of non-decomposing (eg congruent) melting latent accumulator material are not known, however. The transfer to congruent melting material, such as Na 2 S. 5 H 2 O The object of the invention is the object of the invention to develop a latent heat accumulator with non-decomposing melting substances, with which without the use of mechanical means the formation of agglomerates, crusts and impermeable formations with large volume is prevented and at the same time large Description of the essence of the invention Latent heat accumulators with non-decomposing melting substances, for example congruent and eutectic melting substances, tend to form crystals which solidify with agglomerates during solidification. voly m. These are the cause of low heat input and output effects as well as thermal voltages inside the accumulator. The prevention of these inconveniences is achieved according to the invention by an active accumulator filling, which contains three material systems I, II and III and optionally a fourth material system IV, as stated below.

Material system I Consisting of one or more substances, which due to their heat of conversion, e.g. melt heat, and their specific heat capacity exhibits heat accumulation properties, melts without decomposition forming a homogeneous melt and are useful as heat accumulator materials.

According to the invention, the proportion of material system I in the total volume of the active accumulator filling amounts to 50-95% by volume.

Material system II Consisting of one or more components composed of liquid heat transport medium, in which material system I is not soluble or only conditionally soluble. In this case, the density of material system II (PII) and the density of the melt-liquid phase of material system I (PI) according to the invention meet the condition _91 vision, e.g. 0.8 μl, the vapor pressure of the material system I (PDI) and the vapor pressure of the material system II (P) according to the invention fulfilling the DII condition PDI The proportion of material system II of the total volume of the active accumulator filling in the accumulator amounts to 3 to 465,625 6 50% by volume.

Material system III Consisting of one or more surfactants. The proportion of material system III of the total volume of the active accumulator filling of the latent heat accumulator amounts to 0.01 to volume percent. Material system III has the task of forming small crystals when solidifying material system I and preventing adhesions and / or crusts.

Material system IV Consisting of one or more germ formers, which due to their lattice structure effect the germ formation process or trigger heterogeneous germ formation.

According to the invention, the proportion of material system IV of the total volume of the active accumulator filling of the latent heat accumulator amounts to 0 to 20% by volume.

If material system I is not or only slightly undercooled, the proportion of material system IV in the active accumulator filling is lost.

Embodiments The latent heat accumulator according to the invention will be described in more detail with regard to the active accumulator filling with reference to a drawing (figure 1): Material system I: Mg (NO3) 2. 6 H 2 O and MgCl 2. 6 H 2 O as a eutectic mixture with 70% by volume Material system II: Chloro-bromotane CH 2 ClBr with 28% by volume Material system III: Cordesin W with 1% by volume Material system IV: Activated carbon with 1% by volume The 4 material systems are filled in a dense and heat-insulating .J 463 62; 7 container 1 in the form of a mixture such as active accumulator filling 2.

Inside the container 1 a heat transfer medium 3 is arranged so that it is completely covered by the accumulator filling 2. A further heat transfer medium 4 is arranged so that it is surrounded only by steam of material system II in a cavity 5.

The heat supply is carried out through the heat transfer medium 3 enclosed by the accumulator filling 2, the heat removal through the heat transfer medium 4 surrounded by heat transport medium vapor. The heat supply and heat removal take place during three-phase conversion.

In the event of a heat supply above the melting temperature, material system II evaporates. In the event of coincidence with material not yet molten material of material system I, this condenses and material system I melts. The condensation heat emitted by material system II is absorbed by material system I as melt heat.

In the case of heat extraction below the melting temperature, material from material system II evaporates, in this case at a lower pressure than in the heat supply. The heat of evaporation therefore required is taken from the accumulator material (material system I), which solidifies. The steam of material system II is condensed on the heat transfer medium 4 and the released condensation heat is absorbed by the heat transfer medium 4.

In both cases, the heat transfer takes place during intensive blistering with a strong mixing of the accumulator filling, whereby a heat absorption uniformly distributed over the entire accumulator material resp. heat dissipation is achieved. This process, which is known per se, takes place in the case of molten substances without decomposition in the absence of material system III during the formation of agglomerates, adhesions and crusts with a large volume. 463 625 8 This is avoided by adding material system III. It is formed depending on the intensity of the blistering and the amount of material system III crystals with small volume, which form a looser and more permeable filling in the interior of the accumulator.

Material system IV is required to trigger crystal formation during heat extraction and prevent subcooling. fw *

Claims (1)

1. 465 623 PATENT REQUIREMENTS Latent heat accumulator with decomposing melting substances with an active accumulator filling, which must be mixed in an accumulator container, characterized in that the active accumulator filling contains three material systems I, II, III and possibly a fourth material system IV , whereby - material system I consists of one or more substances which, due to their heat of conversion and specific heat capacity, have heat-accumulating properties, on melting form a homogeneous melt, for example the eutectic mixture of Mg (NO 3) 2. 6 H 2 O and MgCl 2. 6 H 2 O with a proportion of 50 to 95% by volume of the total volume of the active accumulator charge, material system II consists of a liquid containing one or more components such as heat transport means, in which material system I is insoluble, the density of material system II (trap) and the density of the molten phase of material system I (fl) satisfies condition f: 5 fi: and the vapor pressure of material system I (PDI) and the vapor pressure of material system II (PDII) satisfy condition P 44 P DI DII and its proportion of the total volume of the active accumulator filling amounts to 3 to 50% by volume, - material system III consists of one or more surfactants and its share of the total volume of the active accumulator filling amounts to 0.01 to 5% by volume, - material system IV consists of one or more germ formers and its share of the total volume of the active accumulator filling amounts to 0 to 20% by volume.