EP4291829A1 - Heat-insulated storage container and method for designing a heat-insulated storage container - Google Patents

Abstract

The invention relates to a storage container and to a method for designing same, comprising a wall (1) that forms the storage container and has an inner face and an outer face, and an insulation layer (2) that rests against the outer face of the wall (1), encloses the storage container and has different thicknesses in different regions (1.1, 1.2) of the wall (1). According to the invention, the insulation layer (2) is thicker in a region (1.1) that has an above-average temperature difference between the inner face and the outer face of the wall (1) than in a region (1.2) that has a smaller temperature difference between the inner face and the outer face of the wall (1).

Description

Thermally insulated storage tank and method of designing a thermally insulated storage tank

5

The invention relates to a heat-insulated storage tank according to the preamble of patent claim 1 and a method for designing a heat-insulated storage tank according to the preamble of patent claim 8.

10

A heat-insulated storage container of the type mentioned is generally known per se, so that no special written proof is required. Such a heat-insulated storage container intended for holding heating circuit medium (i.e. usually water) consists of a wall forming the storage container, having an inside and an outside and a wall lying on the outside of the wall, enclosing the storage container and in different areas the wall with different thicknesses of insulation layer. In the design of such a heat-insulated storage container (first considered in general terms), the thickness of the insulation layer that rests against and surrounds the wall of the storage container that has an inside and an outside is regularly specified. 25

The object of the invention is to improve a heat-insulated storage container of the type mentioned at the outset. In particular, a storage tank with optimized thermal insulation is to be provided. 30 This object is achieved with a heat-insulated storage container of the type mentioned by the features listed in the characterizing part of patent claim 1. In terms of the method, the object is achieved by the features listed in the characterizing part of patent claim 8 . 5

According to the invention, it is objectively provided that the insulating layer is made thicker in an area with an above-average temperature difference between the inside and outside of the wall than in an area with a lower temperature difference between the inside and outside of the wall, although it goes without saying here it is about a temperature difference that occurs during operation, in particular during stationary operation, of the storage container. In terms of the method, the invention provides that an area of the wall with an above-average temperature difference between the inside and outside of the wall during operation of the storage tank is determined and a greater thickness of the insulation layer is defined in the determined area than in any other area of the wall.

In other words, the storage tank according to the invention is characterized in that the thickness of the insulation layer is designed to be oriented to the heat flow through the wall 25 of the storage tank. Depending on the intended use of the storage container or depending on the heat flow, different temperature differences can occur in different areas of the wall. These areas are optionally determined - which can be implemented by a person skilled in the art - by means of 30 practical tests or else by a computer simulation - which is necessary for a person skilled in the art with the appropriate knowledge simulation knowledge is also realizable. Once these areas have been identified, a particularly thick insulation layer is provided there in order to compensate for the temperature differences or to make them more uniform over the entire wall. A storage tank designed or designed in this way is thermally more favorable than one in which no account was taken of the areas in which there is a risk of particularly large temperature differences.

In order, after the insulation layer has been applied, which is preferably done by foaming the storage container, to obtain a storage container that is as smooth as possible on the outside and is therefore easy to handle geometrically and with regard to its further installation, it is also particularly preferred, which will be discussed in more detail below, that the wall in the areas with an above-average temperature difference is designed to be concave on the outside and convex on the inside to accommodate the thicker insulation layer. This requirement also leads to a particularly pressure-resistant storage container. 20

Furthermore, it is particularly preferred, which will be discussed in more detail below, that the storage tank be designed as a defrosting buffer or buffer storage of a heat pump (see, for example, the buffer storage according to DE 102018 25 102 670 A1) and in the housing of the heat pump itself, in particular a heat pump intended for installation inside a building. The storage container according to the invention, which is or can be very compact due to its special design or shape, is particularly well suited for this purpose. In all of the above, it is particularly preferred that the insulation layer is made thicker in the area or those areas where the inside of the wall is colder than the outside of the wall during operation of the storage container. Expressed in terms of the method, it is therefore particularly preferred that, in order to determine the above-average temperature difference, an operating mode of the storage container is selected in which the inside of the wall is colder than the outside of the wall. These stipulations are therefore based in particular on an operating mode of the storage container in which the outside of the wall could fall below the dew point and thus condensate could form. When using the storage container in a heat pump, this is in particular the so-called cooling operation, ie the operation in which the heat pump is used to cool the building.

Other advantageous developments result from the dependent patent claims. 20

The thermally insulated storage container according to the invention and the method according to the invention for its design, including its advantageous developments according to the dependent patent claims, are explained in more detail below with reference to the graphic representation of a preferred exemplary embodiment.

It shows

30

FIG. 1 in section the storage container according to the invention together with its insulating layer; FIG. 2 in perspective the storage container according to FIG. 1 without its insulating layer;

FIG. 3 shows the storage container according to FIG

2; and

FIG. 4 shows the storage container according to FIG. 3 in section along the section line D-D.

The storage container shown in the figures initially consists, in a known manner, of a wall 110 forming the storage container, having an inside and an outside, and a wall 110 lying on the outside of the wall 1, enclosing the storage container and attached to different areas 1.1, 1.2 of the wall 1 insulation layer of different thicknesses 2.

15

Said wall 1 preferably consists of a metallic material.

Furthermore, it is preferably provided that the storage container is formed from two matching half-shells. 20

Furthermore, the storage container preferably has a supply connection 3 and a discharge connection 4 (see in particular FIG. 2).

25

When designing such a storage tank, a thickness of an insulation layer 2 lying against a wall 1 of the storage tank having an inside and an outside and surrounding the storage tank is defined in a known manner. 30 Objectively considered, it is now essential for the storage container according to the invention that the insulation layer 2 is thicker in an area 1.1 with an above-average temperature difference between the inside and outside of the wall 1 than in an area 1.2 with a lower temperature difference between the inside and outside of the wall 1 is formed.

Considered in terms of the method, it is essential for the storage container according to the invention that an area 1.1 of the wall 101 with an above-average temperature difference between the inside and outside of the wall 1 during operation of the storage container is determined and that the insulation layer 2 in the determined area 1.1 has a greater thickness than on one other area 1.2 of the wall 1 is set. 15

With regard to the shape, it is further particularly preferred that the wall 1 is formed concavely on the outside and convexly curved on the inside 20 in the area 1.1 with an above-average temperature difference to accommodate the thicker insulation layer 2.

Furthermore, it is particularly preferred that the wall 1 is curved, in particular corrugated, in an area 1.3 with an above-average internal container pressure to increase the pressure stability of the storage container 25 or that an area 1.3 of the wall 1 with an above-average internal container pressure is determined to avoid deformation 1.1, 1.2 and 1.3 in the context of the aforementioned computer simulation 30 is taken into account accordingly. As explained at the outset, it is further particularly preferred that the storage container is arranged in a housing of a heat pump, in particular a heat pump provided for installation inside a building. Or in other words: According to the invention, a heat pump is provided with a housing and a storage tank of the type described arranged therein. It is particularly preferably provided that the storage container is designed as a defrosting buffer of a heat pump, ie serves in particular to provide heat for defrosting an iced-up evaporator. In this context, it is further particularly preferred that the storage container has a storage volume of less than 30 liters, preferably less than 20 liters, particularly preferably less than 16 liters. For a design that is as compact as possible, it is also particularly preferred that the insulation layer 2 enclosing the storage container has a cuboid shape on the outside.

As also already stated above, it is finally—especially when used in a heat pump in cooling mode—to prevent condensation between the wall 1 and the insulating layer 2 particularly preferably provided that the insulating layer 2 is made thicker in the area 1.1 , on which during operation of the storage container 25 the inside of the wall 1 is particularly cold compared to other areas 1.2 and colder than the outside of the wall 1 or that to determine the above-average temperature difference in a (specific) area 1.1 (and in comparison to other areas 1.2), an operating mode 30 of the storage container is selected, in which the inside of the wall 1 is colder than the outside of the wall 1. As can be seen, the said temperature difference can be positive or negative depending on the mode of operation of the storage tank, ie cold outside and warm inside (e.g. heating mode of the heat pump) or warm outside and cold inside (e.g. cooling mode of the heat pump).

With regard to the condensation mentioned, it is ultimately preferably provided that the insulation layer 2 is at least so thick that the dew point is not undershot at any point on the wall 110 or condensation occurs.

reference list

1 wall

1.1 Area

1.2 Area

1.3 Area

2 insulation layer

3 supply port

4 drain connection

Claims

patent claims

1. Heat-insulated storage tank, comprising a wall (1) forming the storage tank, having an inside and an outside and a wall (1) lying on the outside of the wall (1), enclosing the storage tank and in different areas (1.1, 1.2) of the wall (1) insulation layer (2) of different thicknesses, characterized in that the insulation layer (2) is thicker in an area (1.1) with an above-average temperature difference between the inside and outside of the wall (1) than in an area (1.2) with a lower temperature difference between the inside and outside of the wall (1).

2. Thermally insulated storage container according to claim 1, characterized in that the wall (1) in the region (1.1) with an above-average temperature difference for receiving the thicker insulation layer (2) is concave on the outside and convex on the inside.

3. Thermally insulated storage container according to claim 1 or

2, characterized in that the wall (1) is curved in an area (1.3) with above-average internal container pressure to increase the pressure stability of the storage container.

4. Heat-insulated storage tank according to one of claims 1 to 3, characterized in that the insulation layer (2) enclosing the storage tank has a cuboid shape.

5. Thermally insulated storage container according to one of claims 1 to 4, characterized in that it is arranged in a housing of a heat pump, in particular a heat pump provided for installation inside a building.

6. Thermally insulated storage container according to one of claims 1 to 5, characterized in that it is designed as a defrosting buffer of a heat pump.

7. Heat-insulated storage container according to one of claims 1 to 6, characterized in that the insulation layer (2) is thicker in the area (1.1) where, during operation of the storage container, the inside of the wall (1) is particularly cold compared to others Areas (1.2) and colder than the outside of the wall (1).

8. A method for designing a heat-insulated storage container, in which a thickness of a wall (1) of the storage container having an inside and an outside Ters adjacent insulation layer (2) surrounding the storage tank is determined, characterized in that an area (1.1) of the wall (1) with an above-average temperature difference between the inside and outside of the wall (1) during operation of the storage tank is determined and on the determined Area (1.1) has a greater thickness of the insulating layer (2) than in another area (1.2) of the wall (1).

9. The method according to claim 8, characterized in that, in order to avoid deformation, a region (1.3) of the wall (1) is determined with an above-average internal container pressure and is formed in a curved manner.

10. The method according to claim 8 or 9, characterized in that to determine the above-average temperature difference in an area (1.1), an operating mode of the storage container is selected in which the inside of the wall (1) is colder than the outside of the wall (1). is.