DE3125463A1 - Pressure equalising member in PCM devices, preferably in ice reservoirs - Google Patents

Abstract

The invention is used for the purpose of saving energy in energy stores (energy storage mechanisms) which are filled with latent heat storage material for the purpose of improved utilisation. The invention is chiefly concerned with water reservoirs which are cooled with the aid of heat pumps as far as complete icing. In the case of latent heat storage materials, a change in volume generally accompanies the change in phase. If completely rigid containers, e.g. made from concrete, are used as storage containers, it is necessary to use a device which permits the change in volume without an impermissibly high pressure being exerted on the walls of the storage container. This is achieved in the case of the invention by introducing pressure equalising members of sufficient volume into the storage container. These equalising members can be, e.g., (see Fig. 1) rubber hoses (3) which are filled with air (2) and provided in the storage container (1) around the walls. In the case of water as storage medium, it is sufficient, for example, for the rubber hoses to take up 13 % of the volume of the container in order to protect the container against bursting when the water freezes. <IMAGE>

Description

Dipl. Vlijs. Michael.steel \. ^:: .. ^: " ^: ., ^: . ·. Sheet"

Sohleswiger Str. 45
8500 Nuremberg

Pressure compensation body in latent heat storage * !, preferably in ice storage.

The invention "relates to one or an arrangement of compressible bodies, called pressure compensation bodies, which are placed in a container filled with water Allow volume change when the water freezes and comit damage to the container even if it is complete Avoid icing.

In the course of energy saving techniques, energy storage devices are being used to an increasing extent. In particular, the storage of thermal energy in ice latent storage for the operation of heating heat pumps is currently being used more and more. This improves the efficiency of heat pumps with the heat source outside air at air temperatures below freezing point. During this time, the heat reservoir in the ice store is used as a substitute for the natural heat source air, ie some kind of heat exchanger removes heat energy from the store's contents and thereby freezes it. The problem of the change in volume when the state of aggregation changes, which in the event of complete icing of the storage contents can lead to damage or even destruction of the container, basically arises. The following possible solutions to this problem are known so far:

a \ The container is so elastic that it Can absorb volume expansion even when fully iced up. The same thing will happen in some Kind of movable walls achieved. Disadvantage: rigid containers generally cannot

be used.

bv Non-elastic containers are protected from destruction protected by the fact that the icing is not completely

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dig, e.g. only 80%. The heat pump must be through a. The sensor in the container must be switched off in good time and must no longer withdraw any energy from the ice store »
Disadvantage: no full utilization of the memory content

possible, forced interruption of the

Heat pump operation.

c ^ In non-elastic storage tanks, the ice is prevented from freezing into a solid block, for example by constant stirring or by bubbling gas or liquid through the ice-water mixture. This creates a muddy mixture that hardly exerts any force on the walls of the container and thus excludes destruction.
Disadvantage: expensive devices for stirring or

Mixing.

The invention is based on the object of being able to completely freeze any container filled with water, without the container being damaged or even bursting.

This object is achieved according to the invention in that there is an individual or an arrangement in the container of bodies that are easily compressible, have an elastic and tight outer shell, and the volume of which is dimensioned so that the total pressure in the container, even when it is completely iced up, the permissible pressure does not exceed.

The advantages of the invention are that any, so in particular completely rigid container can be used are, e.g. those made of concrete. The shape can also be chosen as desired. For example, hollow spheres can completely ice up when the pressure compensation body (s) absorb the expansion of the ice. Complete icing in the block is possible at any time, which means that the latent heat of the entire storage capacity can be fully utilized possible. It is not necessary to interrupt the heat pump operation, which means that the The warmth flowing into the environment can be fully utilized

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begins the. Thaw the ice block from the outside again.

It is known that the volume of water increases by about 3% when it freezes into ice. If the freezing process takes place, for example, in a thick-walled, solid hollow sphere completely filled with water, the low compressibility of the ice results in extremely high pressures. If these pressures are to be avoided, the ice must be given space to expand. This is done by the pressure compensating body, which is usually filled with gas and, for example, has an outer cover made of rubber. Instead of gas filling, a large-pored foam that is covered by a dense and elastic outer skin is also possible. Since the ice has a very good plasticity, it shifts when it freezes under very low pressures and compresses the compensating bodies. The total pressure in the container only increases according to the gas pressure in the compensating bodies. The total volume of the compensation body will be between 10% and 20% of the total container volume, depending on the pressure resistance of the container.

The problem of volume change during the phase transition also occurs with other latent storage media. here we can the pressure compensating body can be used in the same way, their number and arrangement in the memory on the physical properties of the storage medium must be coordinated.

The following are two exemplary embodiments of the invention in each case one; j ice bank explains: Fig.1 shows a concrete basin open at the top (in section) (1) with a volume of 10 m. Lying along the walls 4 rubber hoses (2) and 1 hose on the floor that goes with Are filled with air, have a diameter of 0.2 ro and a total length of 41 m. The total volume of smart

χ
before is 1.3 rrr and thus enables expansion

of the ice.

Another possible implementation is AIdTd. 2 (also on average):

In a hollow ball (1) made of solid material with any In the middle, a rubber balloon (2) filled with air is attached, which is half of the capacity Diameter of the storage ball and thus 12.5% of the volume of the ball. This leaves enough space for the ice given for expansion »

Although the ice expands in all directions, enough also one or only a few compensation bodies, since the very good plasticity of the ice allows pressure compensation in the direction the compensating body allows. The heat exchanger for heat extraction is located in the one filled with water Volume of the storage tank. The number and arrangement of the compensating bodies can also meet the respective requirements the heat exchanger can be adjusted.

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Claims (2)

Pressure compensation body in latent heat storage, preferably in ice storage. Patent claims:
f One or any arrangement of compressible bodies, called pressure compensating bodies, which allow the volume to increase when the water freezes in a container (1) filled with water and thus avoid damage to the container even when it is completely iced up, characterized in that a% of their Outer shell (3) consists of an elastic and dense material,
b \ the interior of the pressure compensation body (2) is slightly compressible, c \ the total volume of the Drude compensating body chosen in this way is that even with complete icing up, the total pressure of the arrangement exceeds the permissible pressure in the Container does not exceed. 2. Device according to claim 1, but instead of water with any other latent storage medium in the storage container, with the characterizing features described in a \, \> \ and C \.