CA1167719A - Means for exchange and storage of heat or cold from residual thermal fusion energy - Google Patents

Abstract

Device for exchanging and storing calories or frigories by latent heat of fusion, comprising two essential elements, namely: a container, preferably cylindrical, separated into two capacities by a longitudinal partition, which comprises, on the one hand, an opening for the admission of the coolant, this opening opening into one of said capacities, and, on the other hand, an opening for the exit of the coolant, opening into the other capacity, in such a way that this coolant circulates against current in said capacities; and a set of elementary containers stacked in each of said capacities, these elementary containers being filled with a storage agent for frigories and / or calories having a high latent heat of fusion.

Description

1 ~ 7 ~ 9 The present invention relates to a dls-positive heat and / or cold storage exchanger by latent heat of fusion. Such a device is more particularly intended for the necessary installations both the establishment of a production of calories or frigories in variable quantities in a period given, these installations making it possible to reduce in very important proportions the power of the devices intended to produce the calories and / or the frigories.
We can, in this regard, re: Eerer on demand de breve-t fran ~ ais published on May 22, l9 ~ 1 under n 2,469,678 by the present applicant, who seeks such installation. These installations require resources storage of calories and / or frigories produced, these being redistributed according to needs, the storage capacity being chosen so that the ins-tallation: Eournisse, in a way: instantaneous, the maximum instantaneous power required by the loads of the installation.
The subject of the invention is therefore a device exchanger-store of calories or frigories per cha their latent fusion, comprising two elements essentials:
a) a container, preferably cylindrical, separates into two capacities by a longitudinal partition, which includes, on the one hand, an opening for admission of the coolant, this opening opening into one of the say capacities, and, on the other hand, an opening for the exit from the heat exchanger, opening into the other capacity, in such a way that this coolant circulates against the current in said capacities;
b) a plurality of elementary containers stacked in each of these capacities, these containers elementary being filled with a stock agent frigories and / or calories with high heat . ~.

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More precisely, the i.nvention claimed here is essentially a disposi ~ .if exchanger-storage calories or frigories by latent heat of merger, including device:
- a main container of Lorme elongated divided into two capacities by a partition lon ~ itudinale, these capacities being connected ensernhle to a end of said main container;
- a plurality of elementary containers stacked in said capacities in such a way that coolant circulating in these capacities can go around these basic containers-meet trant homogeneous resistance;
- each basic container with two conEormed hemispheres of ~ ace such that when assembled, they leave an interstitial between them:
allowing circulation of the coolant;
- each hemisphere is filled with an agent to store calories and / or fricJories ~ heat in fusion, - each hemisphere being made in one deformable material to absorb variations of volume resulting from crystallization, and - each hemisphere containing an air pocket : able to produce an expansion specific to the device.
According to an embodiment of this invention, the cylindrical container has, at each of its ex-mites., a plate provided with openings, in particular of holes or slits, intended to trans ~ form the pressure static coolant at dynamic pressure at sound entry into said capacity, this in order to ensure a homogeneous distribution of said coolant throughout the e-changer.

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1 lS77 ~ 9 According to another embodiment of this invention, each basic container constitutes, for example, by a rectangular parallelepiped, has, on each of its large faces, a number of bosses leaving, when stacking these containers in the exchanger, -a free space allowing free circulation-tion of the coolant in the interface.
Other characteristics and advantages of this invention will emerge from the description given below in reference to the accompanying drawings, which illustrate various nonlimiting examples of embodiment. On the drawings:
- Figure 1 is a schematic view, in elevation, of a storage exchanger according to the invention;
- Figure 2 is an end view more large ladder, with partial removal, of a heat exchanger storage device according to Figure l;
- Figures 3 to 5 are respectively plan, elevation and end views of an example of elementary container of the device ... ....
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'7 7 1 9 storage device according to the invention;
- Figure 6 illustrates a variant of a detail of the Fi-gure 2; and, - Figure 7 illustrates a variant of an electronic container m entair.
With reference to the drawings, and in particular to the Figures l and 2, it can be seen that the storage-exchanger device according to the invention comprises takes a container lO, preferably cylindrical to better resist operating pressures. The internal part of this container 10 is divided lO in two enclosures 14-16 via a partition wall, ion longitudinal 12. ~ its two ends, the container has boxes water 36-38, consisting of domed bottoms 32 and 33. The domed bottom 33 is removable, to allow access ~ s inside the cylin- ferrule drique constituting the exchanger lO. The second curved bottom 32 is provided with inlet 18 and outlet 20 pipes of the coolant. So that we can see it in Figure l, the intake pipe 18 opens into the capa-cited 14, and the discharge pipe 20 opens into capacity 16. Thanks with this arrangement, the coolant circulates against the current in the belts 14 and 16 of exchanger 10, as represented by the path in broken lines.
At each end of the shell of the exchanger 10, circular plates Z2, 24 with openings are provided. These plates serve, on the one hand to retain in the exchanger the stacks of elementary containers 34, described below, and, on the other hand, now ter, vis-à-vis the coolant admitted into the exchanger lO, a resistance important compared to the inherent resistance of other elements of the cir-'' . ~:

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~) 71 19 cooked borrowed by the coolant in order to obtain a homogeneous distribution "of the coolant in the exchanger, the openings of the transforming plates the static pressure of the coolant, in water tanks 36-38, in one dynamic pressure in each capacity 14-16. The openings made in the circular plates can be either holes Zl (plate 22, Fi-gure 2), or slots 21 '(plate 22', Figure 6). The storage exchanger further includes a drain 26, a drain 28 and a temperature sensor metric 30.
In each of the capacities 14, 16 of the exchange ~ r-storage device 10, as shown in FIG. 2, stacks are produced of elementary containers 34, which creates a plate exchanger.
We have shown, in Figures 3 to 5, an example of reali-sation of an elementary container 3 ~ L. This is made up of a parallel the rectangular epipede in a deformable material (for example, metal or poly-ethylene) having a number of bosses such as 40, leaving, during stacking, a free space 42 (Figure S) allowing free circulation culation of the coolant in the interface. The elementary containers are filled with a medium for storing heat or cooling energy at strong latent heat of fusion. Hydra-tees, including a soda, or even water.
Preferably, the capacity of elementary containers is small, for example of the order of 2 liters, in order to reduce the harmful sequences of a leak According to the invention, interposed between the stacks of elementary containers 34, in the exchanger-store 10, and the shell -.
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',' -, , 7 ~ 1 9 of this exchanger, a plate ~ of ~ nousse of plastic, by example of polyether with very high compressibility, in order to read a setting of the 3'L containers. According to another characteristic of this invention, each row or multiple of rows of elementary containers can be isolated from its neighbor by interposing a sheet of polyethylene lene, which avoids possible convection currents, having for effect of reducing the volume drained by the coolant in the exchanger 10.
The device described above constitutes an exchanger plate store with excellent filling coefficient ~ su-10 above 75%), the primary of which consists of the coolant circulating in capacities 14-16, this coolant, which can be water, being used read either for the charge of the exchanger-store, or for its discharge, depending on the direction of the temperature differences. Indeed, this calopo: rteur pr ~ -feels a difference in temperature with respect to the crystallization temperatures tion of the medium contained in the elementary containers 34, and, depending on whether this difference is positive or negative, the exchanger-store is charged (crystallization -tion) or discharge (merger). This exchanger makes it possible to obtain an important aunt exchange surface in relation to the volume of the storage medium for basic containers; indeed, this surface is of the order of 1 m 20 for 10 to 15 liters of storage product.
This exchanger-storage can have a power of discharge much greater than the load power, the ratio R of the discharge power compared to the charge power being delineated by f ~ rmole:

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~ ~ B ~ ~ L 9 P log te C - T
R = D = ~ tD ~ es ~ x tsC - T
C ~ tC (es) log teD - T
tsD - T
in which:
PD is the discharge power;
C is the load power;
tD (es) is the temperature difference (input, output) during the discharge;
tC (es) is the temperature difference (inlet, outlet) during charging;
teC is the input temperature during charging;
tsC is the temperature at the outlet during charging;
teD is the input temperature during discharge;
tsD is the temperature at the outlet during the discharge; and, T is the storage temperature.
It was indicated above that the elementary containers were made of a deformable material: we know that during a change-state of state (crystallization - fusion), there is generally a ~ aria-density, therefore a variation in volume; these variations are therefore absorbed by the deformable envelope of the containers 34. In the case water, which has an increase in volume of the order of 9% during crystallization, the problem linked to this increase is resolved by holding in the elementary containers an air pocket which produces an expansion specific to the exchanger-store, This allows lead the necessary expansion to the heat transfer circuit to dimensions reasonable. Furthermore, the state of charge of the exchanger can be checked.
storekeeper (stock status) by measuring the residual network pressure of the In addition, the pressure control of the coolant allows :

~ 3 6 ~ 71 9 to control the creep of the ice, in the case of water, this clui maintains at a constant value the free spaces between elementary containers 34.
Of course, this invention is not limited to limited to the embodiments described and represented, but that it includes all variants.
This is how, in particular, elementary containers can take any desired form, provided, however, that they respond under the following conditions:
10 - external exchange surface / volume ratio meeting the requirements of the exchange, approximately 1 m of exchange surface for 10 liters;
- made of a deformable material to absorb varia-volume tiorls resulting from crystallization;
- possibility of carrying out a homogeneous stacking so that the coolant meets a homogeneous resistance when circulating, in order to avoid ter 2: those not drained during charging or discharging.
Figure 7 shows a variant of a container mentaire consisting of two half-spheres ~ res 45-45 'which, after assembly, allow the circulation of the coolant outside the sphere obtained 20 and between the last two spheres, in the interval 46.
This spherical shape allows self-stacking in the main cylindrical container; it also provides the report port exchange surface / volume specified above. Finally, the axial section of the sphere is preformed so that:
- the exchange nux are not too far from the core to be crystallized;
- the variations in volume due to crystallization are absorbed by : ~:. . '. :
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this section without external deformation of the sphere ~ re (part in broken lines, in Figure 7).

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Claims (7)

The realizations of the invention, about of which an exclusive property or privilege right is claimed, are defined as follows: 1. Heat exchanger-storage device or of frigories by latent heat of fusion, device comprising:
- a main container of elongated shape divided into two capacities by a partition longitudinal, these capacities being linked together to a end of said main container;
- a plurality of elementary containers stacks in said capacities so that a coolant circulating in said capacities can pass around these elementary containers when meeting trant homogeneous resistance;
- each elementary container comprising two hemispheres shaped so that when assembled, they leave a gap between them allowing circulation of the coolant;
- each hemisphere being filled with an agent storage of calories and / or frigories having a strong molten heat;
- each hemisphere being made in one deformable material to absorb variations volume resulting from crystallization, and - each hemisphere containing an air pocket able to produce an expansion specific to the device. 2. Exchanger-storage device according to the claim 1, wherein the ratio of the area external exchange and the volume of each container elementary is approximately 1 m2 of exchange surface for 10 liters of volume. 3. Exchanger-storage device according to the claim 1, further comprising, within the main container and at each of its ends a plate provided with openings intended to transform the static pressure of the coolant in dynamic pressure at its entry into said capacities, thus allowing to obtain a homogeneous distribution of the coolant in the whole device. 4. An exchanger-storage device according to the claim 1, wherein the deformable material is polyethylene. 5. An exchanger-storage device according to claim 1, wherein the deformable material is polypropylene. 6. An exchanger-storage device according to the claim 1, wherein the deformable material is metal. 7. An exchanger-storage device according to the claim 1, wherein the main container is cylindrical.