CZ345596A3 - Heat-insulating wall, process of making such heat-insulating wall and a 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

Ofli as f t e c h n i k

The invention relates to a thermal insulating wall. in a method of making a thermal insulating stand as well as a thermal insulating block.

& asaxadEÚ '5.t ^^

In the construction of buildings as soon as the energy crises of the last decade have been urgent ¹ '· koiv ⁱⁿ keeping the spc trgba sn er cie pro k 1 ima 11 zaoi, especially heating the building, as low as possible. This can be achieved-among other measures, which reduces the passage of heat walls and thus minimizes energy loss of ^{the first;}

w a t h e r i s h o n t o r o s. the eye,

In this context, it is known, for example, to lay the insulating boards on the manufactured tents using glue and / or dowels. In this way they put on. Place the usual insulating materials in the walls = thickness between 4 cm and 15 cm and board sizes up to approx. 0.5 m ^and , for example, from a pile.

DE-GM 36 01 946 is a known foamed structural component which, together with other structural elements of the same type, is used for thermal insulation of a wall. masonry. This known structural element is further provided with horizontally extending depressions which serve to better adhere the plaster applied to the plaster. building element. Furthermore, DE 34 34 021 A1 discloses a thermally insulating molding element and a method of manufacturing a gray material in which one layer of glazing insulating elements is always applied to the seating layer and subsequently a masonry layer is produced on the inside. with protrusions on

ΞΟ ΞΟ® ´ π Š Ϊ Z 1 V. ^Ί: Z í G Π G '· / Λ Cv in G h G G G 5 1 U S -pair vs τ H Í V Lt » T y -r O more generally and Z G1 U. ¹ í C Í elements vsak m CASE ti e k S cent i m 3 G r ú a I can not from the world at ú p 1 n c u t a p e i nou. and Z O 1 et al buildings, thermal i z olaoe is but SP olivě with 11 u s t ym pIs.Š ' windows up super z ask1eni m and from ρ o v d and j ί o í m i frames, j

A highly efficient replacement controlled ventilation device is provided.

heat for heat recovery, a prerequisite for making this passive house. Passive nightlife from koener get i o o houses are bu.aov ·· - who o o o i me řed in the middle:

they give away a small amount of energy.

or it can even be dropped from heating,

With the advanced development of the above passive house components, doo é í Z HG Ζ9.; <Ο '-,' «ΖΟ blidCVY Stď.VSt, ·! n a π 1 ξ s k c sp t □ aiz 31 π m costs ..

As already mentioned. In particular, good thermal insulation is one of the most important requirements for building passive houses. For example, a value of 0.10 W / (mK) is required on the outer wall. This requires a thickness of up to approx. 40 cm. However, such an insulating layer cannot be placed on the wall of the house in known ways.

With respect to the known invention. In the production of heat, the heat insulating deficiency in the state of the art lies in the task of boiling the thermally insulating wall.

In this case, the smuggling of the heat treatment method can be built at a favorable cost. In particular, it must be ensured that thermal insulating elements with a width in the order of magnitude indicated can be securely connected to the supporting walls,

C ontenting.

On the one hand, this is achieved by the heat-insulating wall of claim 1.

Therefore, the wall according to the invention is provided with an outer layer of a plurality of layers of blocks of thermally insulating material, in particular.

EPS hardened foam, Blocks of thermally insulating material are.

in particular, they are made with a thickness of 33 cm to 43 cm, and a. provide excellent thermal insulation of the wall according to the invention. inner layer, made of concrete or more layers to the wall, which also with. s p o!. u.i joints with a composition, in particular mortar. Subsequently, the inner layer is.

zaoglre insulating walls according to the invention produced.

A well-proven method of concrete or blocks, masonry between which there are masonry joints, which are filled with fasteners.

According to the invention, the concrete or bonding agent found in the joints between the blocks of the inner layer is used to securely secure the outer layer of thermal insulating blocks to the inner layer. It should be noted at this point that, according to the invention, the outer layer of thermally insulating blocks is made at least partially in front of the inner layer, of concrete or blocks, masonry. When forming the inner layer of concrete, masonry blocks or concrete or liquid flows in the connecting means, in particular mortar, in the production of internal> / dr γst vv qo to ek kt9 sou ^r j t 5? P to izoi ° I <j. they are formed on their inner sides. In this case, these grooves are possibly aligned with the joints between the blocks of the inner layer, so that the connecting means can flow without problems. Thus, after the concrete or bonding agent has cured, it is also partially present in the grooves of the insulating blocks, so that they are fixedly bonded to the inner layer.

Thus, on the heat-insulating wall according to the invention, very good is provided on the outer layer. thermal insulation with extremely thick blocks of thermally insulating material,

A still new method completely ensures the flow of concrete or mortar through the shelf, which is produced during the production of the inner layer, into the thermal grooves as well. or CH b1 to about ργο ⁿ evné connection between both EMA wall layer according to the invention. Advantageously, the grooves of the thermally insulating blocks, in accordance with standard masonry, are vertically spaced apart, so that the masonry in a standard design can be combined with the described thermal insulating blocks to form a thermally insulating wall according to the invention.

Preferred embodiments of the wall according to the invention are described in claims 2 to 3.

Therefore, it is preferred that the thermally insulating blocks of the outer layer are not only rigidly connected to the inner masonry layer, but a rigid connection is also formed with the blocks lying below and above them. For this connection between superimposed blocks it has proven advantageous to make a groove-tongue connection, in which grooves are formed on the upper and lower sides, in which the tongues are always inserted before the next layer of blocks is laid. Alternatively or additionally, gluing of blocks of superimposed layers may be performed by applying an adhesive.

According to another preferred embodiment, they are between

The rods placed by the individual layers of the thermally insulating blocks. If the contact points between the thermally insulating blocks of the superimposed layers are aligned with the masonry joints, a further improvement of the connection between the inner and outer layers can be achieved by the described rod arrangement. These rods are clamped between blocks of superimposed layers and interfere with adjacent masonry joints. When curing concrete. or the connecting means used, for example, the mortar are.

tie rods fixed in the inner layer. Optionally, a combination of both can be achieved. layers even exclusively with zazde.nycn

-r (S 1_ _Λ odd oríoadv employ an J® preferred are jsstliža.

gravity is placed between blocks of superimposed layers

and. _: ; rj t VV 9 These gravity anchors are in particular provided with p »1ochými staples which is found on the inside <= t f · -.. Π ® tepei né insulating blocks to form a solid s bonding to vnifcřní layers, eventually by adjacent masonry joints, That is sp o j en i

between the inner and outer layers further improved. Furthermore, the gravity anchors are provided on their outwardly directed sides with a screw sleeve in which fastenings or scaffolding can be placed. In addition, any other additional elements can be screwed on, for example, sun protection devices or the like can be mounted on the outside of the thermal insulating wall according to the invention on the anchoring elements described. In the region of the blocks between which such anchoring elements are placed, they are. these are flat and heat insulated so that no undesirable heat conduction can occur through the anchoring elements.

from the inside out.

According to a further preferred embodiment of the heat-insulating wall according to the invention, it has an outer layer thereof. special insulating elements to fit the window or door or window frame. Such elements complement the thermal insulation system to create a reliable thermal insulation wall, and allow the construction of a complete house with an outer layer with excellent thermal insulation.

In order to meet the optical impression requirements of the walls of the invention and the buildings so constructed, it is preferred that the thermal insulating blocks of the outer layer be provided with an outer surface of the outer layer which is a wall. u i i good ops, Pr i d o m gives Přsdnost arcni tsk. Tons of natural materials such as ceramics, natural stone, clinker, plaster and the like, such as s.

For grooves with non-masonry concrete inside:

Inner side for the fertilizer:

The layers have proved to be advantageous if they are dovetailed. Therefore, the grooves have a base which is widened on the surface relative to its width. In this embodiment, the concrete or mortar flowing into the dovetail grooves provides a particularly reliable connection between the two wall layers according to the invention.

According to a further preferred embodiment of the invention, a perimeter insulation and a floor insulation are provided in the region of the lower layer of the thermally insulating blocks. In this measure, the wall according to the invention is advantageously complemented by a practical and also heat-insulating embodiment of the floor area.

According to a further aspect of the invention, there is provided a method of making a heat insulating wall that is possessed / cut.

As mentioned above, in the process according to the invention, at least partially, at least partially, the three insulating blocks bonded together, which consist mainly of rigid foam, are produced therein.

EPS. This first method step of the method according to the invention represents a reversal of the hitherto conventional construction process, in which a plate-shaped thermal insulation is always attached to an already made wall. According to the invention, the inner layer is made of masonry blocks or concrete after the outer layer of thermally insulating blocks has been made. 5 blocks of the outer layer such that the two layers are joined together. Optionally, said steps, namely at least partially fabricating the outer layer of the thermally insulating blocks and subsequently fabricating the inner layer, are repeated several times to fabricate the thermally insulating wall or building from the more thermally insulating walls.

In this connection, the mortar used in the production of the inner layer or the concrete ensures, by means of the said measures, a firm connection between the two layers. Furthermore, the method according to the invention provides advantages in that the thermally insulating sheath of the blocks.

made of thermally insulating material can be built from the inside, which, compared to the traditional way of scaffolding, means facilitating the operation.

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

Therefore, it is advantageous if the layers are at least in the area of the inner and between the several walls to be determined by the leveling concrete. The room is made of insulating bioks, and for this purpose it is laid on a layer, in particular of a thin layer, before the exterior outer layer is made, in particular a thin layer. Finally, it has proved to be advantageous for the floor area in the wall area according to the invention to concret the floor plate, the upper edge of the floor plate coinciding with the upper edge of the blocks 1 and 2.

For a rigid connection between the blocks of the individual layers lying above or above, it is advantageous that in the grooves on the upper side of the blocks the springs are placed before the superimposed layers and / or the adhesive is placed.

The above-mentioned advantages can be achieved by placing the rods and / or gravity anchors before laying the next layer of thermal insulating blocks. For joining between the inner and outer layers, it is advantageous that the blocks of the outer layer are provided with grooves into which, when making the inner layer, concrete or the connecting means between masonry blocks flows. When curing said materials, a strong and reliable bond between the two layers can be guaranteed.

In the process according to the invention, considerable savings in time and cost can be achieved if special insulating elements which are suitable for attaching windows and / or doors are further positioned when making the outer layer of thermal insulating blocks. In this connection, the components to be fastened in these elements can also be fitted / together with the construction of the heat-insulating sheath, so that the building can be closed and the construction can be carried out very quickly.

According to another aspect of the invention, there is provided a thermal insulating block that is suitable for forming an outer layer of a passive house wall,

Thermal insulating bio ··· The cut is described in claim 16.

According to the invention, the block of thermally insulating material has such a sufficient width that a plurality of blocks of blocks can be joined to each other to form the outer layer of the thermal insulating wall. This measure distinguishes the thermally insulating block according to the invention from the same known in the art, with relatively thin and far-plate thermally insulating elements, with which it is not possible to fabricate the outer layer before masonry or concreting the inner layer. Further, the block according to the invention is connectable by means of a suitable connection means.

with the blocks above it and the underlying layers, at least one groove extending in the mounted position, preferably horizontally, is formed in at least one side surface of the block, the position of which is optionally adapted to the masonry joint position, with which multiple layers of blocks are formed combinable.

By the described formation of grooves on the side of the blocks directed towards the inner layer. as described above, a reliable bond is provided between the two layers of the fabricable wall.

Particularly into the described track ¹ ', the bonding means / masonry used, for example, the mortar or the concrete used for concreting, flows, so that, after hardening of these materials,

Provided for firm anchoring of thermally insulating blocks on the inner layer. Advantageously, the grooves based on the masonry standard are arranged vertically spaced apart so that, despite the use of standardized masonry, the grooves are aligned with the joints of the masonry and a secure connection is made between the two layers. In such a way, even in the case of several blocks arranged above one another, a p-described alignment with the joints of the masonry is obtained. If the inner layer is made of concrete, the grooves can be arranged in any number and at any distance, with distances of 20 cm to 30 cm being shown to be advantageous,

According to a preferred embodiment of the block according to the invention, it has grooves in the region of its soda and / or upper side into which the tongues can be inserted in order to ensure a firm connection with and below or above them.

arranged blocks. As already mentioned, a dovetail shape is preferred for the grooves arranged laterally on the blocks and for the flowing of the connecting fluid flowing in the inner layer.

The invention is further explained by way of example, with reference to the accompanying drawings, in which: FIG. 1 shows a perspective view of a corner of a house. 2 shows a perspective view of the corner of the house from the inside with the walls according to the invention, and the soil area.

I I

ú..ěězn.i.Lex!

As can be seen in FIG. 1, the thermal insulating wall according to the invention consists of an outer layer 1.2 of thermally insulating material, and an inner layer 1.4, which in the illustrated embodiment is a masonry. According to the invention, when the wall 1.2 is produced, at least partially the outer layer is first formed. 12, which consists of blocks 2.2. 2 thermal insulating material having a thickness in the range up to 4 cm. In particular, the blocks 22 are measured and formed such that first as shown in FIG. 1, a portion of the outer layer 122 may be formed before the inner layer 1.4 is formed on the inner side.

For a fixed connection between individual blocks 22 outside you are layer U2 has block 2.2. according to the invention in the illustrated embodiment as in FIG. its groove in its installed position, as well as on the two lateral groove surfaces, 22. Thus, if the block 22 according to the invention is viewed as a plate of great thickness, the front and side surfaces are provided with tabs 22. In the illustrated case, the grooves 22 are expediently formed over the entire circumference.

In forming the outer layer 122, tongues 24 are inserted into the grooves 22, which provide a firm connection with a block or block arranged above it, which is also provided with grooves 22 on its sowed or upper surface as well as on its side surfaces. In the illustrated case, two grooves are formed in each Plose, relatively close to the inner and outer surfaces of the thermally insulating block 22, in the illustrated embodiment the springs 2.4 are formed as spring plates.

An insulating element 10 is shown in the region of the left wall section. arranged in particular in the outer layer, which serves to fit the window. In particular, this additional element 16, which also consists of a pre-applied EPS insulating material, allows a flush fit of the window openings. and the following blocks 22 outside. you're layer 12 inset windows.

For fixed connection between

a subsequent masonry made of block 22, the blocks are provided with grooves 26 on their inner sides, which in the depicted embodiment in the installed position run horizontally and are dovetailed, that is to say the grooves 26 are expediently formed with a distance between them. in the block 22, so that when making the inner layer lying on the outer layer 12, the gaps between the individual blocks 32 masonry with respect to their height position with the grooves 26 by this combination of the insulating block. 22 according to the invention, with the garment to be produced on the inner side, can be made from the outside wall with the wall having the right side.

Firm connection between the two layers.

The mortar 52, which is preferably used as a connecting means between the blocks 22, masonry or concrete to be used in concreting the inner layer, flows into the grooves and subsequently strengthens in the grooves 26, so that a reliable bonding between the two layers and reliable fastening the most thick thermal insulating layers from the thermal insulating blocks on the inner layer.

On the upper side of the insulating block 22.

notifiable to. FIG. a gravity anchor 26, which may be in the wall 1.3, is further illustrated. according to the invention used to be put on the outside during the construction process. to place a scaffolding or something similar and which, if necessary, serves on the finished wall to fasten the sun protection devices. Weight anchor 22 with inner clamp? z3 9.hu.jθ cJo joints vs zcfiw. · »5 is?

insulated to prevent heat conduction,

Fig. 2 shows another embodiment of the thermal insulating wall at the inner corner of the building, similar to Fig. 1. In the embodiment shown in Fig. 2, the blocks 2 (3) have grooves 22 only on their upper sides. 2, the groove 22 is wider than the embodiment shown in FIG. 1, and only one groove 22 is provided. The tongues 24 are in this case formed in the form of strips consisting of laminated wood or styropore.

Furthermore, in the embodiment shown in FIG. 2, so-called tie rods are provided to further improve the connection between the outer layer blocks 20 and the blocks 30 of the masonry inner layer.

34, which extend to the region of the tongues 24. * in the manufacture of the inner layer 14, masonry is arranged between the individual blocks of blocks 30. Furthermore, the tie rods 34 are masonry or embedded in the inner layer, thereby supporting the joining effect of the mortar 3.2 or the concrete flowing into the grooves 21. In FIG. However, the distances between the grooves are adapted to these standardized blocks

3.0. masonry. so that, in combination with standardized blocks, masonry for firm bonding between the inner and outer layers of the wall 22 according to the invention can be provided. Supplementary

4 noted on the inside of the block. 32 masonry can be placed plaster 22 ..

In the region r-e of the lower layer of the thermally insulating blocks, it is expedient to realize in FIG. 2 the floor area in the region of the wall 12 according to the invention, in that it is on the ground.

the first leveling layer 22 was first laid.

of thin concrete. On this underlying. leveling layer

2S. The base plate is laid, which is to be seen in the cutting areas in FIG. 2, the bar 42. Subsequently, the first layer of insulating blocks 22 is arranged on the base profile and aligned vertically. After the mortar has set, it is on the underlay.

leveling layer laid in perimeter insulation layers

In the case of the outermost layer, the outermost layer of perimeter insulation may be bonded to the insulating blocks 22, ⁱⁿ this case some form of formwork for the floor plate 44 which is poured out of the concrete. At the same time, the concrete is drained exactly along the bottom edge of the groove, which is located in the insulating box 2.2 ·

Further, a further layer of thermally insulating blocks 22, optionally together with additional window and door elements 16, is positioned in the manner described. When the usual course of construction is reversed, the inner layer is finally produced. At the house. constructed in the manner described, all heavy building materials, namely blocks 22, are now found.

masonry, plaster 22. screed 46 and floorboard 44 inside the heat impermeable building envelope so that an excellent energy store is created, and the energy consumption to heat the interior can be minimized.

3 S: t LI P LI J 4? Ϊ

Claims (5)

PATENT CLAIMS Thermal insulating wall. (10 's: - the outer layer. (12 ') a plurality of blocks (20) of thermally insulating material, in particular a hardened axle EPS, and - an inner concrete layer (14) or a plurality of masonry blocks (30) which are joined together by a suitable fastener (32), in particular mortar. - wherein the blocks (20) on their sides facing the inner layer (14) are provided with grooves (26) in which the concrete is at least partially located, they are not aligned with the joints between the blocks (30) of the inner layer (14) the masonry element (32) is located at least partially in the grooves (26) between the blocks (30). so that the blocks (20) are connected to the inner layer (14), The thermally insulating wall according to claim 1, characterized in that the blocks (20) of superimposed layers are connected together by a groove-tongue connection (22, 24) and / or by an adhesive. The thermally insulating wall according to claim 1 or 2, characterized in that rods (34) extending between the blocks (20 'of superimposed layers) extend into the region of the inner layer (14)'. A thermally insulating wall according to at least one of the preceding claims, characterized in that interlocking blocks (20) of superimposed layers are located between them: securing anchors (28), in particular thermally separated, A heat insulating wall according to at least one of: Γ Γ 5 CÍ C ft 3, Z Q i C í C I “! Π <2Γ O k Li, V y 7 Π · 3 C LI j.1 Cl ~ S> characterized in that the non-layer (12) is further provided with insulating elements (16) which are anchoring windows and / or doors. created for J 1 Cl s j sou on him but M, Z S j me or orní t koti « Thermal insulating wall according to at least one of the preceding claims, characterized in that the block · / (2®) of the outer layer (12) is provided on the outer side with a surface mat with ceramic, natural stone, clinker or plaster . A thermally insulating wall according to at least one of the preceding claims, characterized in that the grooves (26) are formed in the blocks (20) by a ribbed body. Thermal insulating wall according to at least one of the preceding claims, characterized in that perimeter insulation (42) and a concrete floor plate (44) c are formed in the region of the lowest layer of the thermal insulating blocks (20), which are flush with the edge of the blocks. in the most inferior layer, A method for recovering a thermal insulating wall with the steps of: (a ⁾ at least partially making the outer layer of a plurality of layers 1'2. (b) subsequently making an inner layer of concrete or blocks of masonry in the region of the finished outer layer or parts thereof, wherein the concrete or bonding agent placed between the blocks of masonry comes into contact with blocks of the outer layer such that the two layers are joined together, (c) optionally repeating steps <a> and (b). Method according to claim 9, you ₃ Pa, p _u j t ICI in that before forming the outer layer is at least in the region of the inner layer and between the multiple luminous ZHO Vitus me walls reputed to flush soil base leveling layer, Method according to claim 9 or 10, characterized in that after the lower layer of the thermally insulating blocks has been formed, a psrimeter insulation is laid and subsequently a concrete floor slab is poured. Method according to at least one of claims 9 to 11. characterized in that a plurality of springs are placed on the thermal insulating blocks before the superposed layers of the insulating blocks are laid, or an anvil is placed. The method according to at least one of claims 9 to 12, characterized in that according to claim 1, characterized in that the blocks and / or gravity anchors are arranged on the blocks before laying the next layer of thermally insulating blocks. 14, The method according to at least 9. The layers are provided with inner concrete or jointing Method according to at least the outer layers are suitable for holding any one of claims 13 to 13, characterized in that the blocks are outer by grooves into which the masonry flows between the blocks in the layer A device according to any one of claims 9 to 14, characterized in that insulating elements are placed over the fabrication elements which make the windows okenι / π ?? or double-sided. Block (20) of thermal insulating material. - having a sufficient width such that multiple layers of blocks (20) for forming the outer layer (12) of the thermally insulating wall (13) can be joined together, - the block (23) being connectable to the blocks (20) lying underneath and / or above it, - and wherein at least one groove (26) is formed in the at least one side surface of the block (20), extending in a stepped position, preferably horizontally, the position of which is possibly aligned with the masonry joint position with which multiple layers of blocks (20 ') ¹ to form a thermal insulating wall (13), Block according to claim 16, characterized in that the block (23) is provided with grooves (22) in which the tongues (24) can be placed. 13. Block according to claim. 16 or 17, wherein the grooves (26) are. in the side face of the block.