CH669006A5 - SHELL MASONRY. - Google Patents

Description

DESCRIPTION

The invention relates to shell masonry according to the preamble of claim 1.

Shell masonry of the type mentioned are known several times. Shell masonry of this type is generally designed as a double-shell masonry, an inner, thicker wall shell forming the load-bearing wall shell, while an outer wall shell is thinner. The wall shells are arranged at a distance from one another and connected to one another via anchors, the gap between the wall shells generally being filled with insulating material. The individual wall shells are often built from normal bricks. Such double-shell masonry results in relatively good insulating properties, but has some disadvantages. For example, the thinner outer wall shell reacts much more intensely to changes in temperature, and thus also shows larger fluctuations in expansion than the thicker inner wall shell. Accordingly, the wall shells must also be connected with anchors that allow a relative movement of the wall shells. Wire anchors, spring anchors, joint anchors, spiral anchors and the like are used for this. Incidentally, the creation of such a shell masonry is relatively complicated and the heat transfer figures required today can only be achieved with the insulating material inserted into the gap between the wall shells.

The object of the invention is to improve a shell masonry of the type mentioned at the outset in such a way that it enables simpler manufacture and yet results in particularly low heat transfer coefficients.

The object is achieved according to the invention by the characterizing features of claim 1.

Because the shell masonry according to the invention has three wall shells, each of at least approximately the same thickness, the jumps in temperature and thermal expansion between the individual wall shells are not very large and are otherwise the same, so that differences in the thermal expansion between the individual wall shells can be kept small. This allows simple anchors to be used, and the anchors can also run over the three wall shells. Such shell masonry is extremely easy to manufacture, whereby the individual wall shells can be created in the runner association. The fact that simple anchors extending over the three wall shells can also be used results in a further simplification in the manufacture. Nevertheless, such shell masonry provides considerable thermal insulation due to the three wall shells made of insulating stones and the spaces between them, so that a heat transfer coefficient of k <0.4 can be achieved for shell masonry with a thickness of less than 400 mm.

Advantageous embodiments of the shell masonry are described in claims 2 to 14.

Basically, stones of different sizes and masses can be used for such a shell masonry. However, it is particularly advantageous if the insulating stones are designed according to claim 2, so that they can be grasped and processed with one hand (one-hand stone). Dimensions according to claim 3 are particularly advantageous.

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The insulating properties of the insulating stone can be achieved in a variety of ways. For example, hollow stones are possible, the cavities of which are completely or partially filled with insulating material, for example plastic foam. However, an embodiment according to claim 4 is particularly advantageous. The insulating block according to claim 4 results in a substantial reduction in mass due to its high proportion of slotted holes and at the same time increased insulating properties, so that it can be processed more easily, in particular as a one-handed block. In contrast to cavities filled with insulating material, such insulating stones are also inexpensive to manufacture. A further development of the insulating block according to claim 5 is particularly expedient, so that the good insulating properties are also achieved at the vertical butt joints on the head sides of the insulating blocks.

The insulating bricks can be made from a wide variety of materials, such as concrete, fiber concrete, lightweight concrete such as gas concrete, sand-lime brick, plaster and the like. However, an insulating stone made of fired clay is particularly advantageous.

The insulating bricks of the individual wall shells can be connected to one another both in the horizontal and in the vertical joints according to claim 7 with mortar, preferably with insulating mortar. An embodiment according to claim 8 is also possible. Such a shell masonry is expediently designed according to claim 9, since cold bridges caused by mortar are then avoided on the head sides. The use of insulating stones according to claim 5 is particularly advantageous. However, training according to claim 10 is also possible.

The vertical joints of the shell masonry are expediently designed according to claim 11. These vertical joints can either be designed according to claim 13 or preferably according to claim 12, since the air layers give the shell masonry a higher insulating property.

An embodiment of the shell masonry according to claim 14 is particularly advantageous, since individual anchors can be dispensed with here and the manufacture of the shell masonry is considerably simplified by means of the anchors designed as bed joint reinforcement. In addition, the strength of the masonry is significantly increased.

Exemplary embodiments of the shell masonry according to the invention are described in more detail below with reference to the drawing, in which a three-shell shell masonry is shown in detail and in a view of a bearing surface.

The shell masonry shown in the drawing in detail and in view of a bearing surface has the three wall shells 2, 4 and 6, which form a vertical joint 8 between them, which have a thickness d of 10 to 40, preferably 20 to 25 mm. These vertical joints can be filled with insulating material, for example insulating mortar, insulating fibers, insulating plates or the like, but they are preferably open and thus form an insulating air layer. The individual wall shells are connected by anchors 10, which extend over all three wall shells. Such anchors can be distributed over the masonry

Be anchors, preferably the anchors are in the form of a bed joint reinforcement 12. For example, one to two such bed joint reinforcements can be arranged per meter of wall height. Such a bearing joint reinforcement 12 can consist of a grid according to the type shown in the figure or of a material running in a zigzag shape. The bed joint reinforcement can preferably be formed from a wire but from a strip material according to DE-OS 24 02 653.

The individual wall shells are formed by insulating stones 14, which are preferably made of fired clay. These insulating blocks have vertically running slot holes 16, which are continuous from the bearing side to the bearing side. These slotted holes are distributed approximately uniformly over the bearing surface 18 and have a width bi of 4 to 10, preferably 7 mm and a length 1 of at least 50 mm, preferably 65 mm. Between the rows of slots running in the longitudinal direction are arranged longitudinal webs 20 which have a width b2 of 4 to 10, preferably 8 mm. The transverse webs 22 separating the slotted holes in a row of slotted holes have a width b3 which approximately corresponds to the width b2 of the longitudinal webs. The transverse webs 22 are preferably offset from slot row to slot row by half the length 1 of the slot row. A number of the slot holes 16t adjacent to the head sides 24 are open towards the head side and form a common slot hole 26 with adjacent insulating stones, which is generally open, that is to say forms an air layer. However, it is also possible to introduce an insulating material into such a slot hole, for example in the form of an insulating mortar or an inserted insulating plate, for example made of foam plastic.

The individual insulating blocks 14 are preferably made of fired clay and preferably have the following dimensions:

Length L = 250 mm Width B = 115 mm Height H = 140 or 190 mm.

The insulating bricks expediently have a mass of approximately 4 kg or less, so that they make bricking up considerably easier as a one-handed brick. To facilitate handling, the insulating stone can be provided with a hand or preferably a thumb hole. These insulating bricks are walled up in a group of runners, the bricks being joined together in the horizontal joints by mortar, preferably insulating mortar. The top sides 24 of the insulating blocks 14 can also be connected to one another by means of a layer of mortar, but they preferably abut each other as shown in the drawing. It is also possible to connect the insulating blocks on the bearing sides and the top sides with adhesive.

The three-shell masonry of the type shown can be created extremely easily and inexpensively and is characterized by a high insulating property with great strength. With such a shell masonry, a thermal conductivity coefficient of the order of magnitude of k <: 0.4 can be expected for masonry with a thickness of less than 400 mm.

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1 sheet of drawings

Claims (14)

669006 1. shell masonry, in which the wall shells formed from stones, spaced apart from one another are connected to one another by anchors, characterized in that it has three wall shells (2, 4, 6) each of at least approximately the same thickness made of insulating stones (14), wherein the anchors (10) run over the three wall shells (2,4, 6). 2. shell masonry according to claim 1, characterized in that the insulating blocks (14) each have a mass of approximately 4 kg. 2nd PATENT CLAIMS 3. shell masonry according to claim 1, characterized in that the insulating blocks (14) have the following dimensions: Length L = 250 mm Width B = 115 mm Height H = 140 or 190 mm. 4. Shell masonry according to claim 1, characterized in that the insulating blocks (14) each have approximately uniformly distributed slot holes (16, 16i) distributed over the bearing surface (18), from slot to bearing surface, the slot holes (16, 16i) a width (bi) of 4 to 10, preferably 7 mm, and a length (1) of at least 50 mm and the longitudinal webs (20) arranged between the rows of slotted holes have a width (b2) of 4 to 10, preferably 8 mm, and the transverse webs (22) separating the slot holes (16, 16i) of a row of slot holes being offset from slot row to slot row by approximately half the length of the slot holes and having a width (b3) which is approximately the width (b2) of the longitudinal webs (20) corresponds. 5. shell masonry according to claim 1, characterized in that a part of the head sides (24) of the insulating stones (14) adjacent slot holes (16i) are open to the head side. 6. shell masonry according to one of claims 1 to 5, characterized in that the insulating stones (14) consist of fired clay. 7. shell masonry according to claim 1, characterized in that the insulating stones (14) of the wall shells (2,4,6) are each connected to one another by means of mortar, preferably insulating mortar. 8. shell masonry according to claim 1, characterized in that the insulating stones (14) of the wall shells (2,4,6) are each connected by means of adhesive. 9. shell masonry according to claim 1, characterized in that the insulating stones (14) of the wall shells (2,4,6) butt against each other at the head sides (24). 10. Shell masonry according to claim 5, characterized in that an insulating material is arranged in the slot holes (16i) open to the head side (24i) of adjacent insulating stones. 11. Shell masonry according to claim 1, characterized in that the vertical joints (8) between the wall shells (2,4,6) have a thickness (d) of 10 to 40, preferably 20 to 25 mm. 12. Shell masonry according to claim 1, characterized in that the vertical joints (8) between the wall shells (2,4,6) are designed as air gaps. 13. Shell masonry according to claim 1, characterized in that an insulating material, preferably insulating mortar, is arranged in the vertical joints (8) between the wall shells. 14. Shell masonry according to claim 1, characterized in that the anchor (10) as one in certain Horizontal joints arranged bearing reinforcement (12) is formed.