EP0775784A1 - Heat insulating wall, method of construction of such wall and heat insulating block - Google Patents

Abstract

The wall provides heat insulation, and has an outer layer (12) which is formed by layers of blocks (20). The latter are made from a heat-insulating material, which is preferably a hard foam. The wall also has an inner layer (14) of concrete, or of layers of masonry (30) which are connected with a suitable binder (32), which is preferably mortar. The sides of the blocks which face the inner layer have grooves (26), which are at least partly filled by the concrete, or are aligned with the joints on the masonry of the inner layer. The alignment is such that the binder fills the grooves at least partly, in order to connect the blocks to the inner layer.

Description

The invention relates to a heat-insulating wall, a method for creating a heat-insulating wall and a heat insulation block.

Since the energy crises of the last few decades, building any type of building has been an urgent task to keep energy consumption for air conditioning, in particular heating the building, as low as possible. This can be achieved, among other things, by measures that reduce the heat transfer through the walls and thus minimize the energy loss from the heated interior to the environment.

In this context, it is known, for example, to apply insulation boards to the walls created using adhesive and / or dowels. In this way, insulation materials with thicknesses between 4 cm and 15 cm and panel sizes up to approx. 0.5 m ² can usually be attached to the walls. For example, a component made of expanded plastics is known from DE-GM 86 01 946, which is attached to the masonry together with other such components for thermal insulation of a wall. This known component also has horizontally extending depressions which serve the better adhesion of a plaster to be applied to the outside of the component. Furthermore, DE 34 34 021 A1 discloses a thermally insulating shaped element and a method for producing masonry, in which one layer of the plate-shaped insulating elements is plugged onto the underlying layer, and subsequently a layer of masonry is created on the inside, with projections on the heat-insulating shaped elements used to align the masonry joints.

However, these known thermal insulation elements at most have a thickness of a few centimeters and cannot guarantee a largely complete thermal insulation of a building. Excellent thermal insulation, together with a dense building envelope, windows with super glazing and corresponding frames, as well as a demand-controlled ventilation system with a highly efficient heat exchanger for heat recovery is an essential prerequisite for the construction of a so-called passive house. Passive or low-energy houses are buildings that emit such a small amount of energy into the environment that it may even be possible to do without heating. With the progressive development of the mentioned components of passive houses, it is now possible to build such buildings with an acceptable effort.

As mentioned, good thermal insulation is one of the most important requirements for the construction of passive houses. For example, a k-value of 0.10 W / (m ² K) is required on the outer wall. This requires a thickness of an insulation layer in the range of up to approx. 40 cm. However, such an insulation layer cannot be attached to the wall of a house using the known methods.

In view of the inadequacies of the thermal insulation systems known in the prior art, the present invention is based on the object of creating a heat-insulating wall, a method for producing a heat-insulating wall and a heat-insulating element suitable for this purpose, with the aid of which a passive house can be created inexpensively. In particular, it must be ensured that thermal insulation elements with a width in the order mentioned can be securely connected to the load-bearing walls.

The solution to these problems is achieved on the one hand by a heat-insulating wall according to claim 1.

Accordingly, the wall according to the invention has an outer layer composed of several layers of blocks made of thermal insulation material (preferably EPS rigid foam). The blocks of thermal insulation material are preferably made with a thickness of 35 cm to 40 cm, and provide excellent thermal insulation of the wall according to the invention. Furthermore, the wall has an inner layer made of concrete or several layers of bricks, which are connected to one another with a suitable connecting means, preferably mortar. Consequently, the inner layer of the thermal barrier wall according to the invention is made in a proven manner from concrete or masonry, between which there are masonry joints that are filled with a connecting means.

According to the invention, the concrete or the connecting means located in the joints between the stones of the inner layer is used for the secure fastening of the outer layer of thermal insulation blocks to the inner layer. It should be noted at this point that, according to the invention, the outer layer of thermal insulation blocks is at least partially created in front of the inner layer of concrete or masonry. When the inner layer is created from concrete or masonry, the concrete or the connecting means, preferably mortar, which is liquid when the inner layer is created, flows into the grooves which are formed in the thermal insulation blocks on the inner sides thereof. Here, these grooves are optionally aligned with the joints between the stones of the inner layer in such a way that the connecting means can flow in without problems. After the concrete or the connecting agent has hardened, it is therefore partially also in the grooves of the thermal insulation blocks, so that they are firmly connected to the inner layer.

On the thermal insulation wall according to the invention, very good thermal insulation is thus ensured on the outer layer by the extraordinarily thick blocks of thermal insulation material. Furthermore, the flow of the concrete or mortar used in the creation of the inner layer into the grooves of the thermal insulation blocks ensures a firm connection between the two layers of the wall according to the invention in a completely new way. Advantageously, the grooves of the thermal insulation blocks are spaced apart from one another in the vertical direction, if appropriate on the basis of the masonry standard, so that masonry can be combined in a standardized embodiment with the thermal insulation blocks described to form the thermal insulation wall according to the invention.

Preferred embodiments of the wall according to the invention are described in claims 2 to 8.

Accordingly, it is preferred if the thermal insulation blocks of the outer layer are not only firmly connected to the inner layer of masonry, but also a firm connection is made to the blocks below and above. For this connection between the blocks of layers lying one above the other, a tongue and groove connection has proven to be advantageous in which grooves are formed on the top and bottom sides of the blocks, into which spring elements are inserted before the next layer of blocks is placed. As an alternative or in addition, the blocks of layers lying one above the other can be glued by applying an adhesive.

According to a further preferred embodiment, drawstrings are attached between individual layers of thermal insulation blocks. If the joints between the thermal insulation blocks of layers lying one above the other are aligned with the masonry joints, then another arrangement can be achieved by the arrangement of tension bands described Improvement of the connection between the inner and the outer layer can be achieved. These drawstrings are clamped between the blocks of superimposed layers and extend into the adjacent masonry joint. When the concrete or the connecting agent used, for example mortar, cures, the tapes are fastened in the inner layer. If necessary, the two layers can also be connected exclusively via the walled-in drawstrings.

For special applications, it is advantageous if gravity anchors are attached between the blocks of layers lying one above the other. These gravity anchors preferably have a flat tab, which extends on the inside of the thermal insulation blocks to form a firm connection into the inner layer, optionally into an adjacent masonry joint. This further improves the connection between the inner and outer layers. Furthermore, the gravity anchors have on their outward-facing side a screw bushing in which fastenings or scaffolding can be attached. Any other additional elements can also be screwed on. For example, sun protection devices or similar objects can also be attached to the outside of the thermal insulation wall according to the invention on the anchor elements described. In the area of the blocks between which such anchor elements are attached, these are flat and thermally insulated, so that no undesired heat conduction from the inside to the outside can take place via the anchor elements.

According to a further preferred embodiment of the thermal insulation wall according to the invention, its outer layer also has special insulation elements which are suitable for the precisely fitting reception of windows and / or doors or their frames. Such elements complement the thermal insulation system according to the invention to form a reliable thermal insulation wall and allow the creation of a complete house with an outer layer with excellent thermal insulation.

In order to meet the requirements for the visual appearance of the wall according to the invention and of a building formed thereby, it is preferred that the thermal insulation blocks of the outer layer are provided on their outside with surface materials which ensure a good appearance. Architectural materials such as ceramics, natural stone, clinker, plaster and similar materials are preferred.

For the grooves in the thermal insulation blocks on the inside, it has proven to be advantageous for the connection to the concrete or masonry of the inner layer if they are dovetail-shaped. As a result, the grooves have a groove base that is widened on the surface with respect to their width. In this embodiment, the concrete or mortar flowing into the dovetail-shaped grooves provides a particularly reliable connection between the two layers of the wall according to the invention.

According to a further preferred embodiment of the invention, perimeter insulation and a concrete base plate are formed in the area of the lowest layer of the thermal insulation blocks, which is flush with the upper edge of the blocks in the lowermost layer. This measure advantageously complements the wall according to the invention with an expedient and also heat-insulating design of the floor area.

According to a further aspect of the invention, a method for producing a heat-insulating wall is presented, which is described in claim 9.

As mentioned above, in the context of the method according to the invention, an outer layer is first at least partially created from a plurality of layers of heat insulation blocks which are placed one on top of the other and preferably consist of EPS hard foam. This first method step of the method according to the invention represents a reversal of the previously usual construction sequence, in which thermal insulation in the form of panels was always attached to an already created wall. According to the invention, the creation of an inner layer of masonry or concrete takes place after the completion of the outer layer of thermal insulation blocks. Here, the concrete or a connecting means introduced between the bricks, preferably the mortar, comes into contact with the blocks of the outer layer in such a way that the two layers are connected to one another. If necessary, the above-mentioned steps, namely the at least partial construction of an outer layer from thermal insulation blocks and the subsequent creation of the inner layer, are repeated several times in order to create a thermal insulation wall or a building from several thermal insulation walls.

The mortar or concrete used in the creation of the inner layer ensures a firm connection between the two layers through the measures mentioned. Furthermore, there are advantages in the method according to the invention in that the thermal insulation cover can be built up from blocks of thermal insulation material from the inside, which, compared to the work required in a conventional manner from a scaffold, makes the work easier.

Preferred embodiments of the method according to the invention are described in claims 10 to 14.

Accordingly, it is advantageous if at least in the area of the inner layer to be created and between several walls to be created before the outer layer is created the soil a cleanliness layer, preferably made of lean concrete, is applied. The lowest layer of thermal insulation blocks is then created, and then it is preferred to install perimeter insulation in layers in the area between the walls to be created. Finally, for the formation of the floor area in the area of the wall according to the invention, it has proven advantageous to concrete a floor slab, the upper edge of the floor slab corresponding to the upper edge of the blocks of the lowest layer.

For a firm connection between the blocks of individual layers lying one above the other, it is preferred that spring elements are applied in grooves on the top of the blocks before the overlying layer is placed on top, and / or that an adhesive is applied.

Furthermore, the above-described advantages can be achieved by attaching tension bands and / or gravity anchors before laying on the next layer of thermal insulation blocks. For the connection between the inner and the outer layer, it is preferred that the blocks of the outer layer have grooves into which concrete or the connecting means between the bricks flow when the inner layer is created. When the materials mentioned cure, a reliable and firm connection between the two layers can be ensured.

Within the scope of the method according to the invention, considerable time and cost savings can be achieved if, when creating the outer layer from thermal insulation blocks, special insulation elements are also attached, which are suitable for receiving windows and / or doors. As a result, the components to be accommodated in these elements can also be installed together with the creation of the thermal insulation envelope, so that the building can be locked and the expansion can be carried out one floor at a time.

According to a further aspect of the invention, a thermal insulation block is presented which is suitable for forming an outer layer of the wall of a passive house.

The thermal insulation block according to the invention is described in claim 16.

According to the invention, the block of thermal insulation material has a sufficient width that several layers of blocks can be joined to create an outer layer of a thermal insulation wall. This measure distinguishes the thermal insulation block according to the invention from the comparatively thin and largely plate-shaped thermal insulation elements known in the prior art, with which it is not possible to create an outer layer before bricking or concreting an inner layer. Furthermore, the block according to the invention can be connected to the blocks below and above layers by means of suitable connecting means. Finally, at least one groove, which is preferably horizontal in the installed position, is formed in at least one side surface of the block, the position of which groove may be adapted to the position of a masonry joint of a masonry, with which several layers of blocks can be combined to form a heat-insulating wall.

As described above, the described formation of grooves on the side of the blocks facing the inner layer ensures a reliable connection between the two layers of the wall to be created. In particular, the connecting means used in masonry, for example mortar, or the concrete used for concreting flows into the grooves described, so that after the hardening of these materials, the thermal insulation blocks are firmly anchored to the inner layer. Based on the masonry standard, the grooves are advantageously in a vertical direction from one another spaced so that when using standardized masonry there is an alignment of the grooves with the masonry joints, and a secure connection between the two layers is established. Furthermore, the grooves in the blocks may have to be arranged in such a way that the described alignment with the masonry joints results even when there are several blocks arranged one above the other. If the inner layer is made of concrete, the grooves can be arranged in any number and with any spacing, spacing from 20 cm to 30 cm having proven to be advantageous.

According to a preferred embodiment of the block according to the invention, in the area of its lower and / or upper side it has grooves into which spring elements can be inserted in order to ensure a firm connection with the blocks arranged below and / or above. As mentioned, a dovetail shape is preferred for the grooves formed on the side of the blocks in order to incorporate the connecting means which is liquid when the inner layer is created.

Fig. 1

eine perspektivische Ansicht einer Hausecke von innen, deren Wände erfindungsgemäß aufgebaut sind; und

Fig. 2

eine perspektivische Ansicht einer Hausecke von innen mit den erfindungsgemäßen Wänden und einem Bodenbereich.

The invention is explained in more detail below by way of example with reference to the accompanying drawings. Show it:

Fig. 1

a perspective view of a corner of the house from the inside, the walls of which are constructed according to the invention; and

Fig. 2

a perspective view of a house corner from the inside with the walls according to the invention and a floor area.

As can be seen in FIG. 1, the thermal insulation wall according to the invention consists of an outer layer 12 made of thermal insulation material and an inner layer 14, which in the embodiment shown is designed as masonry. According to the invention When the wall 10 is created, the outer layer 12 is initially at least partially built. This consists of blocks 20 made of thermal insulation material, which have a thickness in the range of up to 40 cm. In particular, the blocks 20 are dimensioned and designed in such a way that, as shown in FIG. 1, part of the outer layer 12 can first be erected before the inner layer 14 is subsequently created on the inside.

For a firm connection between the individual blocks 20 of the outer layer 12, the block 20 according to the invention in the embodiment shown has grooves 22 both on its upper surface in the installed position and on the two side surfaces. If the block 20 according to the invention is thus regarded as a plate with a comparatively large thickness, the end and side surfaces of the plate are provided with the grooves 22. In the case shown, the grooves 22 are expediently formed all around.

When the outer layer 12 is erected, spring elements 24 are inserted into these grooves 22, which ensure a firm connection to the block arranged above or to the side, which is also provided with the grooves 22 on its lower and upper surface in the installed position and on the side surfaces. In the case shown, two grooves are formed comparatively close to the inner and outer surfaces of the thermal insulation block 20 in each surface. In the embodiment shown, the spring elements 24 are designed as spring plates.

In the area of the left-hand wall section, a special insulation element 16, which is arranged in the outer layer, is shown, which is used to precisely fit a window. In particular, this additional element 16, which also consists of pre-coated EPS insulating material, enables the remote openings to be fitted precisely and the subsequent insertion of a window.

For a firm connection between the blocks 20 of the outer layer 12 and the masonry of bricks 30 to be erected subsequently, the blocks 20 are provided on their inner sides with grooves 26 which, in the embodiment shown, run horizontally and are designed in the form of a dovetail. These grooves 26 are expediently formed according to the masonry standard spaced apart in the block 20, so that when creating the inner layer adjacent to the outer layer 12, the joints between individual bricks 30 correspond in terms of their height with the grooves 26. Through this combination of the thermal insulation block 20 according to the invention with the masonry to be erected on the inside, a firm connection between the two layers can be ensured when creating the inner layer 14.

The mortar 32, which is preferably used as a connecting means between the bricks 30, or the concrete that can be used when concreting an inner layer, namely flows into the grooves 26 and subsequently solidifies in the grooves 26, so that for a reliable Connection between the two layers and a reliable attachment of the extremely thick thermal insulation layer of thermal insulation blocks is ensured on the inner layer.

On the top of the thermal insulation block 20 to be seen on the right in FIG. 1, a gravity anchor 28 is also shown, which can be used in the wall 10 according to the invention to attach scaffolding or the like to the outside during the construction process, and optionally on the finished wall, for example the attachment of sun protection devices. The gravity anchor 28 extends with a tab on the inside into a masonry joint and is thermally insulated to prevent heat conduction.

FIG. 2 shows a further embodiment of the thermal insulation wall according to the invention on the inner corner of a building in a representation similar to FIG. 1. In the embodiment shown in FIG. 2, the blocks 20 are only provided with grooves 22 on their upper sides. 2, the groove 22 is wider than in the embodiment shown in FIG. 1, and there is only one groove 22 at a time. The spring elements 24 are designed in this case in the form of strips made of plywood or polystyrene.

Furthermore, in the exemplary embodiment shown in FIG. 2, to further improve the connection between the blocks 20 of the outer layer and the bricks 30 of the inner layer, so-called tension bands 34 are present, which extend into the area of the spring elements 24 and when the inner layer 14 is created between individual ones Layers of bricks 30 are arranged. As a result, the drawstrings 34 are walled or concreted in the inner layer and the connecting effect of the mortar 32 or concrete flowing into the grooves 26 is supported.

In Fig. 2 it can also be seen that 30 bricks with a greater height than in the layers below are used in the area of the upper layers of bricks. The distances between the grooves 26 are, however, adapted to these standardized bricks 30, so that in combination with standardized bricks a firm connection between the inner and outer layers of the wall 10 according to the invention can be ensured. In addition, it should be noted that a plaster 36 can be attached to the inside of the bricks 30.

In the area of the lowermost layer of thermal insulation blocks 20, an expedient design of a floor area in the area of the wall 10 according to the invention can be seen in FIG. 2. In this case, a cleanliness layer 38 is first made on the ground Lean concrete applied. A base profile is applied to this cleanliness layer 38, a strip 40 of which can be seen in the cutting areas of FIG. 2. A first layer of insulating blocks 20 is then arranged on the base profile and aligned perpendicularly. After the mortar has set, a perimeter insulation 42 is laid in layers on the cleanliness layer. In the top area of the top layer of the perimeter insulation, the insulation blocks 20 can be glued. In this way, the formwork for the base plate 44, which is poured from concrete, is formed to a certain extent. Here, the concrete is removed exactly along the bottom edge of the groove, which is located in the insulation block 20.

In the manner described, further layers of thermal insulation blocks 20 are subsequently attached, optionally together with the additional elements 16 for windows and doors. In reverse of the normal course of construction, the inner layer is finally created. In a house constructed in the manner described, all heavy building materials, namely the bricks 30, the plaster 36, a composite screed 46 and the base plate 44 are thus located within the thermally sealed building envelope, so that an excellent energy store is formed, and the energy requirement for the Warming of the interior can be minimized.

Claims (18)

Insulating wall (10), with: - An outer layer (12) from several layers of blocks (20) made of thermal insulation material, preferably EPS rigid foam, and an inner layer (14) made of concrete or several layers of bricks (30) which are connected to one another with a suitable connecting means (32), preferably mortar, - The blocks (20) on their sides of the inner layer (14) facing are provided with grooves (26) in which there is at least partially concrete, or with the joints between the stones (30) of the inner layer (14) in such a way are aligned so that the connecting means (32) between the bricks (30) is at least partially in the grooves (26) so that the blocks (20) are connected to the inner layer (14). Thermally insulating wall according to claim 1,
characterized in that
the blocks (20) of layers lying one above the other are connected to one another by tongue and groove connections (22, 24) and / or an adhesive. Thermally insulating wall according to claim 1 or 2,
characterized in that
between the blocks (20) of layers of tension strips (34) lying one above the other, which extend into the region of the inner layer (14). Thermally insulating wall according to at least one of the preceding claims,
characterized in that
securing anchors (28) are attached between blocks (20) of layers lying one above the other, which are preferably thermally separated. Thermally insulating wall according to at least one of the preceding claims,
characterized in that
the outer layer (12) also has insulation elements (16) which are designed to accommodate windows and / or doors. Thermally insulating wall according to at least one of the preceding claims,
characterized in that
the blocks (20) of the outer layer (12) are provided on the outside with a surface material, preferably ceramic, natural stone, clinker or plaster. Thermally insulating wall according to at least one of the preceding claims,
characterized in that
the grooves (26) in the blocks (20) are dovetail-shaped. Thermally insulating wall according to at least one of the preceding claims,
characterized in that
a perimeter insulation (42) and a base plate (44) made of concrete are formed in the area of the lowest layer of the thermal insulation blocks (20), which is flush with the upper edge of the blocks in the lowest position. Procedure for creating a thermal insulation wall with the steps: (a) at least partially creating an outer layer from a plurality of layers of heat insulation blocks, preferably made of rigid EPS foam, (b) subsequently creating an inner layer of concrete or bricks in the area of the finished outer layer or parts thereof, the concrete or a connecting means, preferably mortar, inserted between the bricks coming into contact with the blocks of the outer layer in such a way that the two layers are connected to one another will, (c) repeating steps (a) and (b) several times, if necessary. Method according to claim 9,
characterized in that
Before creating the outer layer, a cleanliness layer is applied to a leveled soil at least in the area of the inner layer and between several walls to be created. A method according to claim 9 or 10,
characterized in that
After creating the lowest layer of the thermal insulation blocks, a perimeter insulation is laid, and then a concrete floor slab is poured. Method according to at least one of claims 9 to 11,
characterized in that
spring elements or an adhesive is applied to the thermal insulation blocks before the overlying layer of thermal insulation blocks is placed thereon. Method according to at least one of claims 9 to 12,
characterized in that
Tension bands and / or gravity anchors are arranged on the blocks before the next layer of thermal insulation blocks is placed on them. Method according to at least one of claims 9 to 13,
characterized in that
the blocks of the outer layer have grooves into which concrete or the connecting means between the bricks flows when the inner layer is created. Method according to at least one of claims 9 to 14,
characterized in that
When creating the outer layer, insulation elements are attached that are suitable for the admission of windows and / or doors. Block (20) of thermal insulation material, - Which is of sufficient width that a plurality of layers of blocks (20) for creating an outer layer (12) of a heat-insulating wall (10) can be joined together, - wherein the block (20) can be connected to blocks below and / or above (20), - And wherein in at least one side surface of the block (20) at least one groove (26) which is preferably horizontal in the installed position is formed, the position of which is optionally aligned with the position of a masonry joint of a masonry with which several layers of blocks (20) are used Formation of a heat-insulating wall (10) can be combined. Block according to claim 16,
characterized in that
the block (20) has grooves (22) in which spring elements (24) can be attached. Block according to claim 16 or 17,
characterized in that
the grooves (26) in the side surface of the block (20) are dovetail-shaped.

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