DE20002611U1 - Thermal insulation - Google Patents

Description

HEINZ DIMMERLING PATENT ATTORNEY

10.02.2000
RIT0001ENG

Ritter Energy and Consolar Energy Storage Environmental Technology
GmbH & Co. KG and Control Systems GmbH
Ettlinger Str. 30 Dreieichstr. 48
76307 Karlsbad 60594 Frankfurt

Thermal insulation

The invention relates to a thermal insulation, in particular of a cylindrical hot water tank, according to the preamble of claim 1, which has a weakly elastic insulating material designed as flat plates.

Such thermal insulation, which regularly consists of molded parts due to the low elasticity of the insulating material, is known, for example, from DE 44 10 215 A1. The known thermal insulation consists of a dimensionally stable foam body. The foam body is preferably composed of two half-shells that are tightly connected to one another.

A disadvantage of the known thermal insulation is that it can only be used for a specific container. This makes it necessary to produce different molded bodies for different containers and to keep them in stock.

If you want to avoid using different molded bodies, you have to build the thermal insulation from a material with great elasticity. For example, DE 195 10 490 A1 describes insulation for heat storage units in which the insulation is made from an elastic foam, such as one based on polypropylene or polyethylene.

However, it is also known from DE 296 00 455 U1 to construct a heat-insulating element for hot water tanks from originally flat rigid foam panels, which are provided on the outside with a covering layer made of a material with high tensile strength and on the inside with a flexible reinforcement that prevents bending back significantly beyond the flat extension and a soft foam layer. The panels have hook strips on two of their front sides, by means of which the front sides can be connected to the panels when encasing a tank. Although the outer layer made of a material with high tensile strength and the inner layer made of soft insulation material mean that the rigid foam panels can be bent, they still offer relatively great resistance to bending. Attaching the heat insulation to a hot water tank is correspondingly difficult.

Furthermore, a thermal insulation is known which essentially consists of rigid foam panels which have wedge-shaped recesses on one side. The wedge-shaped recesses make it easier to bend the rigid foam panels so that they can be adapted to round containers. However, it is complex to mill the wedge-shaped recesses into the rigid foam panels.

It is an object of the invention to design a thermal insulation as mentioned above in such a way that it is easy to produce, easy to handle and its insulating effect is high.

The solution to this problem results from the features of the characterizing part of claim 1. Advantageous developments of the invention result from the subclaims.

According to the invention, the insulating material has groove-shaped recesses on its side facing the body to be insulated, which were created by the mold during the foaming process. By means of the groove-shaped recesses, which advantageously extend over the entire length of the insulating material, the weakly elastic insulating material can be easily bent in a direction transverse to the longitudinal direction of the recesses. This means that the insulating material can be designed as panels and can be easily adapted to a cylindrical hot water tank in particular. To adapt to hot water tanks with a relatively small diameter or to hot water pipes, the depth of the recesses must be relatively large. Depending on the diameter of the tank to be insulated, the depth of the recesses can be about 60 to 95 percent, for example 90 percent of the thickness of the insulating material. If the diameter of the body to be insulated is larger, it would be sufficient if the depth of the recesses were about 50 percent. If the insulation material only needs to be bent slightly, it would be sufficient if the depth of the recesses was only about a third or a quarter of the thickness of the insulation material.

Because the recesses are made during the foaming process, the insulation panels can be foamed as finished elements. This has a very positive effect on the production costs, because an additional work step to create the recesses is not required. In addition, the surface of the recesses according to the invention is stronger due to the foaming than if the recesses are subsequently milled into the insulation panel. It is particularly advantageous if the insulation panels are made of EPP (expanded polypropylene) or EPS (expanded polystyrene).

The width of the recesses is advantageously chosen so that it tapers in a wedge shape, so that in the case of curved insulation panels the surfaces almost touch each other, the recesses being arranged at such a distance from one another that thermal insulation is created which is bent into a circle or polygon.

Advantageously, the width of the recesses in the groove base is smaller than at the groove opening. This advantageously ensures that in the curved

Depending on the condition of the insulation material, the recesses become thin, parallel-walled slots whose walls are located a short distance away from each other or, ideally, just touch each other.

In a further special embodiment of the invention, the insulating material has a spacer on its side facing the body to be insulated, so that a gap is formed between the insulating material and the body to be insulated. The gap creates an air cushion that has a heat-insulating effect. It is particularly advantageous if the distance between the insulating material and the body to be insulated, i.e. the thickness of the air cushion, is approximately three to four centimeters. The low height of the gap suppresses the circulation of air in the gap. The height of the gap can also be less than three centimeters and be, for example, two centimeters. Depending on the structural conditions and the ambient conditions, the distance should be selected so that an optimal compromise is achieved between the heat insulation due to the thickness of the air cushion and the suppression of air circulation within the gap formed by the spacer.

The circulation of air in the gap can also be reduced by the spacer having at least one ring-shaped element which completely encloses the body to be insulated. The ring-shaped element divides the gap, so that the air in the gap can only circulate within the partial space. It is particularly useful if several elements are provided, so that a plurality of gaps are created.

It is also particularly advantageous if the ring-shaped element consists of segments which are arranged on the insulation panels. For this purpose, the ring-shaped element is expediently made of a suitable, soft material. By arranging the segments of the ring-shaped element on the insulation panels, the spacer can be produced in a very simple manner.

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An embodiment of the invention is also particularly advantageous in which the body to be insulated has a surface that reflects heat radiation. It is particularly advantageous if the body to be insulated is coated with a film that reflects heat radiation. The reflective surface significantly increases the thermal insulation. The surface that reflects heat radiation can be produced in a simple manner by using a reflective film. In addition, the degree of thermal insulation can be easily adjusted by using different films. The surface that reflects heat radiation can cover the container to be insulated completely or partially.

In a further special embodiment of the invention, a base plate is provided which has a surface that reflects heat radiation on its side facing the container to be insulated. The base plate advantageously prevents heat from being emitted downwards by radiation.

It is particularly advantageous if the base plate is tightly enclosed by the lower edge of the thermal insulation attached to the container wall. This creates an almost hermetically sealed space formed by thermal insulation in which the container to be insulated is located. This has a very positive effect on the thermal insulation. In the last-mentioned embodiment, it has proven particularly advantageous to arrange the container on feet made of a material with low thermal conductivity. The feet extend through appropriately designed openings in the base plate. However, the feet can also stand on the base plate.

Further details and features of the present invention will become apparent from the following description of a particular embodiment with reference to the drawing.

It shows

Figure 1 shows the lower part of a thermal insulation according to the invention

provided container in schematic representation from the side in section and

Figure 2 shows the arrangement shown in Figure 1 in plan view.

As can be seen from the figures, a cylindrical container 2 has an aluminum-coated surface 6. The aluminum coating of the surface 6 consists of an aluminum foil that has been glued to the container 2. An insulating material 1, which consists of an EPP rigid foam, extends around the container 2. The insulating material 1 has groove-shaped recesses 3 on its side facing the container 2, the depth of which is approximately eighty percent of the thickness of the insulating material 1. The recesses 3 are arranged at a distance from one another that corresponds to approximately a quarter of the radius of the neutral zone of the curved insulating material 1, that is, approximately a quarter of the radius that reaches to the middle of the insulating material thickness. Thus, approximately twenty-four recesses 3 are arranged on the circumference of the container 2. The recesses 3 extend over the entire length of the insulating material 1, that is, over the entire height of the container 2.

The insulating material 1 consists of panels which are attached close to one another on the wall 6 of the container 2. The recesses 3 are made using special foam molds in the foaming manufacturing process, so that no material is lost through abrasive post-treatment processes such as milling, cutting or piercing to achieve the curvature capability.

On its side facing the container 2, the insulation material 1 has a spacer 4. The spacer 4 consists of elements which are made of a soft material and extend over the entire length of an insulation plate 1 so that they form a completely closed ring around the container 2.

Several rings arranged at a distance from one another are arranged between the insulating material and the wall of the container 2.

The spacer 4 forms a gap 5 between the insulation material 1 and the wall of the container 2, or several gaps are formed by several elements arranged in a ring shape.

The container 2 stands on plastic feet 8, which have a high thermal resistance
have. A base plate 7 is also arranged beneath the container 2, which is tightly enclosed by the thermal insulation 1 arranged around the container wall. The plastic feet 8 are designed in such a way that an air cushion of about forty to fifty millimeters thick is formed beneath the container 2. The base plate 7 also has a heat radiation on its side facing the container 2.
reflective foil 6.

Claims (11)

1. Thermal insulation, in particular of a cylindrical hot water tank ( 2 ), which has a weakly elastic insulating material ( 1 ) designed as flat plates, characterized in that the insulating material ( 1 ) is foamed and has groove-shaped recesses ( 3 ) on its side facing the body to be insulated ( 2 ), which are created by the tool mold during the foaming process. 2. Thermal insulation according to claim 1, characterized in that the insulating panels ( 1 ) consist of EPP (expanded polypropylene) or EPS (expanded polystyrene). 3. Thermal insulation according to claim 1 or 2, characterized in that the length of the recesses ( 3 ) extends over the entire length of the plates ( 1 ). 4. Thermal insulation according to one of claims 1 to 3, characterized in that the width of the recesses ( 3 ) in the groove base is smaller than at the groove opening, the grooves ( 3 ) being designed such that when the insulating material ( 1 ) is placed around the body to be insulated ( 2 ), the walls of the grooves ( 3 ) approximately touch each other in the region of the groove openings. 5. Thermal insulation according to one of claims 1 to 4, characterized in that the insulating material ( 1 ) has a spacer ( 4 ) on its side facing the body to be insulated ( 2 ), so that an intermediate space ( 5 ) is formed between the insulating material ( 1 ) and the body to be insulated ( 2 ). 6. Thermal insulation according to one of claims 1 to 4, characterized in that the spacer ( 4 ) has at least one annular element which encloses the body to be insulated ( 2 ). 7. Thermal insulation according to one of claims 1 to 6, characterized in that the body to be insulated ( 2 ) has a surface reflecting thermal radiation. 8. Thermal insulation according to one of claims 1 to 7, characterized in that a base plate ( 7 ) is present which has a surface reflecting heat radiation on its side facing the container to be insulated ( 2 ). 9. Thermal insulation according to claim 7 or 8, characterized in that the body to be insulated ( 2 ) and/or the base plate ( 7 ) is coated with a film ( 6 ) reflecting thermal radiation. 10. Thermal insulation according to claim 9, characterized in that the base plate ( 7 ) is tightly enclosed by the lower edge of the thermal insulation attached to the container wall. 11. Thermal insulation according to claim 9 or 10, characterized in that the body to be insulated ( 2 ) stands on foot elements ( 8 ) which have a high thermal resistance.