NL7906510A - DEVICE FOR INSULATING HEAT AND AT THE SAME TIME EXTRACTING HEAT ENERGY IN A BUILDING. - Google Patents

Description

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Artus Feist, Bergisch Gladbaeh Federal Republic of Germany

Device τοογ the isolation of heat and at the same time the finning of heat energy at a building.

The invention relates to a device for insulating heat and at the same time recovering heat energy in a building, wherein the outer walls and possibly also the roof are covered with a heat-insulating material 5 and wherein this material is covered with a facade material.

In the search for new solutions for better energy use in heating buildings and in the search for new energy, the buildings must be insulated on the one hand and surfaces must be created on the other, 10 from which heat can be removed and converted into heat by means of a heat pump. heat with a higher temperature. In order to solve the first goal, it is known to coat the outer walls and possibly also the roof of a building with a heat-insulating material.

For this purpose, for example, glass fiber or foam plastic strips are used. It is known to apply solar collectors to the roofs of buildings to solve the second stated purpose. These absorb the immediate heat radiation and bundle it on pipe bundles, for example, through which water is led. This water is heated up and fed to a heat consuming appliance.

However, the large outer surfaces of a building, i.e. the outer walls, remain unused according to the prior art. There are several reasons for this. One reason for this is that as a result of the daily sweeping of the sun from east to west, the outer walls are exposed to the direct radiation of the sun for only a few hours.

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In addition, in the north and in the shade of the fangs, there is no immediate radiation from the sun at all. With a high position of the sun, an unfavorable angle of attack is obtained. Therefore, the 5 solar collectors mounted on the outer walls will only explore with a poor rexlement.

The high manufacturing and assembly costs of this are not well made. Moreover, it is very difficult and expensive to maintain and clean the solar collectors mounted on vertical outer walls. The largest outer surfaces 10 of a building, namely the outer walls, are therefore not used according to the prior art for finning heat energy from the environment.

The present invention aims to use the largest, heat-insulating material-coated outer casings for the finning of environmental heat energy. In order to achieve this object, the invention is characterized in that tubes in reciprocating loops are placed on the heat-insulating material and are connected to the primary circuit of a heat pump. A medium that can store the heat is passed through the tubes. In the simplest case and in general this is more vague. As a difference with the finning of heat energy with the help of solar collectors, the heat energy with the tubes becomes extensive, that is said to be included on 25 large surfaces. Thus, a small temperature drop or a small difference from the temperature at the secondary side of the heat pump is also utilized. In addition, the pipes lie on the already fibrous heat-insulating material. The heat explored from the outside of the pipes is thus fully transferred to the medium passed through them and does not flow into the outer walls of the building. All outer walls of the building, possibly including the roof surfaces, are covered with pipes. The heat from the environment is thus extensively used. Therefore it does not sweep like a 790 65 1 0

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3 north-facing outer wall has never been exposed to the direct radiation of the sun or other outer walls or parts of outer walls for other reasons only have a small temperature difference compared to the secondary circuit of the heat pump. As a difference with the solar collectors, the pipes once installed need not be maintained.

In order to simplify the laying and fixing of the pipes and of the heat-insulating material 10 and in order to be able to apply this also in a large thickness, an efficient embodiment is provided, in which the heat-insulating material consists of separate plates and in which the devices for holding the pipes are arranged on the outside thereof. As 15 separate parts, the plates can of course be applied to the outer walls much more easily and adapted to the local conditions than the large webs consisting of glass fibers or flexible plastic foam.

Since, according to the invention, they simultaneously have devices for holding the pipes, a special working phase is omitted here.

In another effective embodiment, the plates with the tubes held by them are covered with a welded wire net, which is screwed and covered with a facade layer. The welded wire net holds the tubes in and between their holding devices. At the same time, the welded wire net is a good base for applying coarse or fine plasterwork. This is effectively given a rough surface. This creates a large area for the transfer of the heat from the environment or the atmosphere to the facade layer and thus to tubes *.

The plates can be attached to the outer walls and to the roof with wall hooks or dowels. According to the invention, it is proposed particularly advantageously that the plates are glued to the outer walls and to the roof. A particularly firm and durable connection between the plates and the outer walls and the roof is then created, when the plates have at least one hole with an increasing diameter starting from the bottom thereof, sail into the adhesive applied on the outer wall and on the roof to form from a gag. Due to the increasing diameter of the hole, the adhesive plug also has an increasing diameter. After curing, anchoring of the plates on the outer walls 10 and on the roof is thus created. Preferably the adhesive is a cement mortar.

This is applied to the outer walls and the plates are pressed onto it. The cement mortar penetrates the holes of the various plates. As a result of the increasing diameter of the holes, plugs of cured cement mortar are formed herein. The plates cling to this. These cannot shift, because the holes must then be drawn past the likewise conical plugs of cement mortar. Between the holes of the plates and the plugs of the cement mortar, an effect of a zvaluv-20 tail joint occurs. When using fast-setting cement mortar, the plates need only be pressed briefly and then hold on by themselves.

According to the invention, the plates consist of a base plate of heat-insulating foamed plastic 25 with upright cylindrical studs disposed thereon, which are equally spaced in mutually parallel rows, the studs having different diameters, the studs having the same diameter each in one row the rows of the studs of different diameters alternate, the studs of the adjacent rows being spaced apart, and the hole in the studs of the larger diameter being spaced apart. The base plate made of foamed plastic can be manufactured in any thickness. This gives the 35th heat insulation and gives the plate the mechanical strength 7906510 * * 5. The pipes consisting of a flexible, cold-resistant plastic can be laid in different patterns between the studs of different diameters. They are laid set back and forth 5 straight tracks and elbows connecting them. The ends of a tube loop are connected to the primary circuit of a heat pump. It depends on the local conditions how many pipe loops the pipes consist of.

It has been found effective that the diameter of the hole changes steadily over the two sections, the diameter of the first section extending from the underside increasing more than over the second section thereafter. The hole is thus divided into sections of different strong conicity. The part adjoining the bottom side has a large conicity. Thus, here the effect of the zvaluv tail joint is particularly great. The diameter of the hole increases less strongly over the second part. This means that the volume of this section, relative to its length, is smaller. Accordingly, less mortar adhesive penetrates this section. This also reduces the use of the expensive mortar adhesive. There is something else to add. The mortar adhesive has a higher heat conductivity coefficient than the foam which forms the plate. The heat insulation of the building obtained with the plate is thus reduced by the penetrated mortar adhesive. As a result, only as much mortar adhesive has to penetrate into the holes as is necessary for fixing the plates on the outer surfaces of the building and for cleaving them using the mortar adhesive. Because this clinging is stronger in the first portion adjacent to the bottom of the plate than in the further course of the hole, the mortar adhesive contributes less to this anchoring as it penetrates further into the hole. It is sufficient that 7906510 ► * 6 bleaching from the first part, which serves for clamping, is about 10 # of the total length of the hole ·

Preferably, several holes are present in the studs of a larger diameter. It is particularly advantageous to make five holes, one of which is in the middle and the other four are arranged 90 ° offset on a circle around the center thereof.

Through-holes through the total thickness or height of the plate facilitate the manufacture of the plate. It is foamed in molds from polystyrene or from another foamable plastic. The through holes are formed with cores. The conicitext of the holes facilitates removal from the molds.

It has already been mentioned that the mortar penetrated in the second part of a hole contributes less to anchoring the plate and moreover deteriorates its heat-insulating properties. In an efficient embodiment, the hole is designed as a blind hole. Such blind holes can also be conically shaped with special measures. The diameter of this blind hole has been found to be effective between about 20% and about 60% of a larger diameter stud. Only one such blind hole is made in a stud.

The heat-insulating retaining plate according to the invention must insulate the buildings completely as much as possible and reduce the radiation of heat.

To achieve this goal, the base plate is made thicker. According to the invention, the thickness of the base plate 30 is approximately 30 mm or approximately equal to the height of the studs.

Embodiments of the invention will now be further elucidated on the basis of the description and the accompanying drawings, in which: 1 is a partial perspective view of a building, wherein the outer walls and the floor surrounded by them are covered with plates according to the invention; Fig. 2 is a partial perspective view of an outer wall with plates, tubes, etc. placed thereon; Fig. 3 is a partial perspective view of an embodiment of a plate according to the invention; FIG. 1 is a longitudinal section through a plate mounted on an outer wall; FIG. 5 is an enlarged view of clinging the slab with the cement mortar at the location indicated by V in FIG. 4; FIG. 6 is a plan view of a stud in the direction of arrow VI in FIG.

Fig. 7 is the same cross section as Fig. U, with an additional indication of how the panel is screwed to the wall of the house and how a facade panel is fitted; Fig. 3 is a longitudinal section through a second embodiment of the plate according to the invention; Fig. 9 is a bottom view of this plate viewed in the direction of line IX in Fig. 8; fig. 10 is a schematic representation of a building and of the connection to the primary circuit of a heat pump.

Fig. 1 shows the corner of a building with two outer walls, of which the plastering work has partly been broken away. The plates underneath the plastering work are shown with the studs and the pipes running between them and the partially exposed welded wire net. Details are shown in large scale in Fig. 2. The plates 12 consist of the base plates 14 with the underside 16 and the upright studs 18 with a large diameter and the studs 20 with a small diameter. These are arranged in parallel rows 7906510 * * 8. The studs 18 with a large and the studs 20 with a small diameter are spaced apart. In the illustrated embodiment, the large diameter studs 18 have five holes. These consist of a hole 22 in the middle and of four holes 2l + arranged around it on a circular arc. Tubes 26 are placed between studs 18 and 20. They run along straight tracks 28 and elbows 30 connecting them. The plates 12 are attached to the outer wall 32 of a building, to which they are attached by means of the mortar adhesive 3¾. As will be explained in detail, this penetrates holes 22 and 2l +. On the studs 18 and 20 there are mats consisting of a welded wire net 36. At mutual distances they are secured with bolts 38. A layer 1 + 0 of piece A-15 doorwork is applied to the welded wire net 36.

Plate 12 is shown in detail in FIGS. 3 to 6. It can be seen that the holes 22 and 2k consist of a first short section 1 + 2 and a second large section 1 + 1 +. Here the conicity, respectively the opening angle at the first short part 1 + 2 is greater than at the second longer part 1 + 1 +. As Fig. 5 indicates, the mortar adhesive 3b penetrates into the first part b2 and partly also into the second part 1 + 1 + where it cures. A plug 1 + 6 is hereby formed, with which the plate 12 is held. Five such plugs are provided in each larger diameter stud 20. These ensure a secure attachment of the plate 12 to the outer wall 32. In order to obtain an even better fixing of the plate, bolts 30 1 + 8 can be arranged in dowels 50 in the outer wall 32 according to fig.

These are each screwed into the center hole 22. According to the embodiment in Fig. 7, mats of welded wire net 36 or ribbed stretch mesh are placed on the cams. These are held by the bolts 38 screwed into the holes or directly into the cams 35. Mortar consisting of 7906510 V * 9 a plastic which improves the properties is still pressed in the welded wire.net. Facade panels 52 can hereby be adhered.

In Figs. 8 and 9, the second embodiment 5 of the plate 12 provided with the blind holes 51 * is shown.

In this embodiment, a single blind hole 51 is provided under and in each stud 18, respectively. Pig. 8 shows in the top half a blind hole 5 to which a vent channel 56 connects, and in the bottom half a blind hole 56 without such a channel.

From the foregoing it appears that the plate 12 can be easily attached to the outer walls 32.

Likewise, it can also be installed on flat and steep roofs. When the plate is applied to a wall of a house, it can be coated with facade plates 52 or simply with plastic. When the plate is applied to the outer surfaces of a house, it insulates the outer surfaces almost ideally from the surroundings, due to its heat-insulating properties. The degree of insulation 20 is determined by the plastic used for the plate and by the thickness and height of the base plate 1U, respectively. The tubes 26 lie between the studs 18 and 20. These are filled with a liquid medium, for instance water.

Fig. 10 schematically shows the example of an application. In a building 58, the outer walls and the roof are covered with plates and the pipes are placed between their studs. These are made up of two pipe loops 60. These lead to the primary circuit 62 of a heat pump 6½. This raises the temperature to a higher value and introduces a heat transfer agent, for instance again water, into the secondary circuit 66. This runs to a central heating in the interior of the building 58.

Likewise, it can run to hot water appliances.

A heat accumulator can also be located between the primary circuit 62 and the heat pump 6k, which is not the subject of the invention 7906510 * rv 10.

The present embodiment thus fulfills the double stated objective, namely to insulate a building against heat radiation and at the same time to provide a surface 5 on which heat from the environment can be absorbed. Ideally this leads to a heating of the building, which is sufficient without additional heat being supplied by burning oil, gas or coal * <7906510

Claims (12)

1. A device for insulating heat and at the same time recovering heat energy from a loom, the outer walls of which, and possibly also the roof, are covered with a heat-insulating material and wherein this material is covered with a facade material, characterized in . that tubes (26) are placed in reciprocating loops (28, 30) on the heat insulating material and are connected to the primary circuit (62) of a heat pump (6¾). Device according to claim 1. characterized in that the heat-insulating material consists of separate plates (12) and on the outside thereof devices for holding the tubes (26) are arranged. Device according to claims 1 and 2, characterized in that the plate (12) with the tubes (26) held by it are covered with a welded wire net (36), it is screwed on and covered with a facade layer. 20 k. Device according to claims 1 to 3, characterized in that the plates (12) are mounted with wall hooks and dowels on the outer walls (32) and on the roof * 5 * Device according to claims 1 to 3, characterized in that the plates (12 ) are attached to the outer walls (32) 25 and to the roof. 6. Device according to claims 1 to 5, characterized in that the plates (12) have at least one hole (22) extending from the underside thereof, with an increasing diameter, in which the plates arranged on the outer wall (32) and on the roof adhesive (3¾) penetrates to form a plug (k6). Device according to claims 5 and 6, characterized in that the adhesive (3¾) is a mortar adhesive. Device as claimed in claim 6, characterized in that the plates (12) consist of a base plate (11 *), which consists of a heat-insulating foam plastic, and cylindrical studs (18, 22), which are raised thereon, equal distances are arranged in mutually parallel rows, the studs having different diameters, the studs of the same diameter each being arranged in one row and the rows alternating with the studs of different diameters, the studs of adjacent rows mutually spaced 10 and the hole (22, 2k) is provided in the larger diameter studs (18). Device according to claim 8, characterized in that the diameter of the hole (22, 2l *) always changes constantly over two parts, the diameter 15 being stronger over the first part (1 * 2) extending from the bottom (16). then increases over the second connecting part (1 * 1 *). Heat insulating retaining plate according to claim 9, characterized in that the first part (1 * 2) 20 is approximately 10% of the total length of the hole (22, 21 *). Device according to claim 10, characterized in that. that several holes (22, 2l *) have been made. 12. Device according to claim 11, characterized in that five holes (22, 2l *) are provided, one hole (22) of which is arranged in the middle and the other four holes (2l *) are displaced by 90 ° arranged on a circle around its center. 13. Device according to claim 6, characterized in that the hole is a blind hole (5 * 0. 11 *. Device according to claim 6, characterized in that the diameter of the blind hole (S1HG is between about 20% and about 60 % of the diameter of the larger diameter stud (18). Heat insulating retaining plate according to 790 65 1 0 claims 5 to 1 tot, characterized in that the thickness of the base plate (15) is approximately equal to the height of the studs (18, 20) « 16. Device substantially as described in the description and / or shown in the drawings. 7906510