SE415845B - Procedure for erecting walls and hollow block for this purpose - Google Patents

Abstract

The heat-insulating capacity of a hollow block made of light clinker material can be enhanced if a filling 15 of heat-insulating material is inserted in the cavities 11- 13. Each insulating element is compressed as it is inserted, so that it acquires less or the same volume as the surrounding cavity and the material is chosen such that, upon subsequent handling, it expands out of the cavity and forms tenons which jut beyond the top and bottom sides of the block. In the building of a wall, mortar is distributed along the inner and outer side of the wall, so that the tenons from the insulating material break the cold bridge formed by the masonry joints in conventional masonry work. <IMAGE>

Description

7811170-5 the site keeps the insulating material compressed within the block, as well that in connection with masonry of the wall, the insulating material is sounded expanded by the_space between the blocks that is normally filled with mortar.

It is advisable to form the blocks with at least three rows through holes and at the masonry lay mortar over them outer rows, but leaves at least the middle row free from mortar.

You can also provide the end edges of the blocks with a groove in line with the middle row of holes, and in the notches at each other inverted block ends fit into a heat-insulating material body, which has a greater height than the block.

A preferred embodiment is characterized in that one who insulating material chooses mineral wool and preferably manufactures man blocks with a substantial content of lightweight clinker balls.

The invention will be described below with reference to showing to the accompanying drawings, which are examples of a embodiment within the scope of the appended claims, and there Fig. 1 shows in principle a lightweight clinker block provided with 'compressed insulation material, Fig. 2 shows how a lightweight clinker block can be filled with insulation material, Fig. 3 schematically illustrates the size relationship between a cavity and an insulating body lowered therein, Fig. Ä shows how blocks can be arranged to during transport prevent length extension of the insulating bodies, Fig. 5 shows a method of transporting blocks from factory to construction site, and Fig. 6 shows a part of a wall during completion.

Fig. 1 shows one suitable for practicing the invention lightweight clinker block 10, provided with three rows throughout, in turning position vertical cavities 11, 12, 13. The outer cavities are offset relative to the middle ones, with a note 14 corresponding to about half a cavity, is formed in each of the blocks end walls, in the extension of the middle row. K The cavities are filled with an insulating mass 15 (only shown in some of the cavities), e.g. of mineral wool. That will Frnmgå uv den nFterPö1Jnndu hnnkrlvnln fi en kommer Luolurmnsnun I associated with the insertion into the cavities to be compressed, so that they 7811170-5 the individual insulating bodies, when the block is set free, can expand and then will shoot outside the top and bottom of the block.

If the normal thickness of a wall joint is H, select the compression so that the insulating bodies can expand substantially equal in both directions in the height direction of the block, ie. appropriate H / 2 upwards and downwards respectively. That way you will get a thermal insulation inside the wall joint, which breaks the cold bridge obtained in the same. During masonry, the blocks are displaced half a block length in relation to each other in each second subsequent layer, and an insulating body in an overlay layer will then collide with parts of two bodies in a sub- horizontal layers. You then get three essentially continuous lanes of insulating material inside the wall joint - see more in connection with Pig. 6.

Fig. 2 schematically indicates how to proceed filling of insulating material. Block 10 stands on a transport band 16, and is passed a station where the insulating material is be in rolls 17, 18, 19 hanging over the strap. The width of the material webs are adapted to the length extension of the rooms 11 - 13.

The insulating material is passed through a feeding machine, indicated by 20, which compresses the material, cuts it off pieces of suitable length and push them down into the cavities.

Fig. 3 is intended to schematically illustrate the proportions between a cavity 11 and an insulating body inserted therein in its cross-sectional moderately compressed conditions. The body should have an uncompressed length which approximately by the dimension H exceeds the block 10, and thus the height of the cavity. As a final insertion step is compressed the body in the longitudinal direction, so that it is completely moved within the block contour.

From the conveyor belt 16, the pre-filled blocks are set on a pallet 21 and arranged so that blocks in a layer insulates the insulating bodies 15 in an underlying layer compressed. When the pallet is fully loaded, a cap 22 is removed plastic film all over and shrink tightly around the blocks, whereupon also the insulating bodies in the upper layer of blocks are kept down.

Fig. Ü is intended to illustrate how the blocks will be work to keep the insulating bodies compressed, though '7811170-5 the blocks on the pallet will be arranged with intersecting longitudinal shoulders.

Fig. 6 shows a portion of a wall under construction, wherein the joints between the blocks 10 are denoted by H. It is seen how the bodies 15 inserted in the cavities 11 - 13 protruded above the plane of the block and forms rows of pins, which protrude into it area where the mortar is to be spread. As pointed out earlier corresponding losses will occur in the event of an overriding - offset - blocks to fit between pins in a sub-block, so that you get basically unbroken insulating strips between the block layers.

In the notes 1ü which are formed at each short end of a block can either be fitted with insulating bodies at the factory with "half" width, or you can fit in the masonry manufactured insulating blocks in opposed grooves 14, and in this way break.the cold bridge even at the vertical joints.

At the masonry, the mortar is conveniently placed strings 24 along the long sides of the block row, so that one gets one air space divided only by the extended pins of the insulating bodies centrally in the block row, and the strings 24 of mortar in part penetrated by other insulating pins.

'“' With a mortar suitable for the purpose, the mill can alternatively, all barriers are placed between the insulating bodies.

The insulating bodies can be manufactured from various known, hardy materials, but mineral wool has proved particularly suitable, because it can be easily shaped into bodies of suitable size play and after compression reacts at such a rate that the blocks become manageable without the insulating material having time to grow out of very.

Claims (7)

7811170-5 PATENT CLAIMS A method of constructing walls with hollow stone blocks, comprising cavities open at at least horizontal joint surfaces, characterized in that at least a substantial part of the cavities in the individual block (10) is provided with a compressed body (15) before masonry. of heat-insulating, elastic material, which in the free state has a larger volume than the enclosing cavity (11-13), that the material body is compressed within the block before masonry, by covering the cavity openings, and that when masonry of the blocks masonry is laid in such a way that a substantial part of the material bodies can expand within the space between the blocks, which is built up by the joint (H). Method according to claim 1, wherein a block (10) is used with at least three rows of continuous cavities (11-13), characterized in that mortar is laid over the outer rows (11, 13) but leaves at least the middle one. row (12) free from mortar. A method according to claim 1 or 2, wherein block (10) is used with a groove (ïh) in each end face in line with the middle row (12) of cavities characterized in that in grooves at each other inverted block ends include at least one heat-insulating body of material (23), which has a greater height than the block. Ä. A method according to claim 3, characterized in that a compressed material body of such size is enclosed in each groove (14) before masonry of the blocks (10) that it expands at least half the joint thickness U outside the groove when exposed. 7811170-s 6 5. Holes for building walls comprising open cavities at at least horizontal joint surfaces, characterized by a body (15) of heat-insulating, elastic material enclosed in the cavities (11-13), which is kept temporarily compressed by covering the cavity openings. . 6. A method according to claim 4, characterized in that the insulating material consists of mineral wool. Hollow stone blocks according to one of Claims 5 or 6, characterized in that the block (10) is substantially made of lightweight clinker balls, and in that it is provided with three relatively offset rows of continuous cavities (11-13). ), including the insulating bodies (15).