SK607190A3 - Tranversally punched shaped piece with longitudinal through slots - Google Patents

Abstract

A perforated brick (1) possesses vertical through cavities (2) which are arranged, in plan view, in a plurality of rows (3) running next to one another. The sound-insulating property can be increased to a surprisingly high degree while retaining a constant heat-insulating property and load-carrying capacity, if the ratio of the maximum cavity length (L), measured in the direction of the row (3), to the minimum distance (D) between two adjacent cavities (2) belonging to two different rows (3) is 1:1 to 6:1, and the sum of the minimum distances (X), measured in the direction of the row (3), of the cavities (2) of a row (3) from one another and from the brick edge is 12% to 18% of the brick width (B) extending in the direction of the rows (3). <IMAGE>

Description

The invention relates to a transversely perforated building fitting with vertically extending slots, which are arranged in plan view along side-by-side rows.

In the hitherto known transverse perforated bricks, blocks and fittings, the main attention was paid to improving the thermal resistance value, which was achieved by increasing the proportion of the overall cross section of the lightening slots on the cross section of the building block or fitting.

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The ratio of the lengths of the lightening slots to the spacing of the individual rows of slots in these known building blocks and fittings is often above 10: 1. This achieves good thermal insulation, but at the same time substantially reduces the strength and load-bearing capacity of the building block. :

The so-called Berger mass law is used to calculate sound damping in building components, according to which the value R _{w of} sound damping is a function of the wall mass per unit area, expressed in kg / m ² . The following relationship applies:

Rw = 32.4 Ig / m '/ - 26 [dB] where m' is the mass of the wall per unit area in kg / m ² .

It also appears that the theoretically determined values of the sound attenuation R _w strongly depend on the geometry of the arrangement of the lightening slot arrangement, the deviations caused by this different geometric arrangement being up to 15 dB at the same wall weight per unit area.

It is an object of the present invention to provide a transverse perforated fitting of this kind which, while maintaining a high load bearing capacity and good thermal insulation properties, is characterized by a high degree of sound damping.

This object is achieved by a transverse perforated fitting according to the invention, which is based on the ratio of the maximum slot lengths measured in the direction of the row of elongated slots to the minimum spacing between two adjacent rows of elongated slots is from 1: 1 to 6: 1. the minimum spacing between adjacent slits in one row of these slits and the spacing from the edges of the fitting is equal to 12% to 18% of the width of the fitting in the direction of the rows of slots.

It has been shown in many experiments that maintaining these ratios of different fitting values represents a very good compromise with respect to the heat resistance requirements of the fitting and thus produces a building fitting that has excellent thermal resistance and noise damping properties.

It has also been shown that the ratio between the lengths of the transverse slots and the spacings between the slots of two adjacent rows is essential for the attenuation and absorption of noise, the proportion of the connecting bridges between adjacent slots of one row in the overall width of the building block.

Particularly in this field of sound attenuation, a significant effect of the geometrical parameters of the fitting has been proven by experiments, which significantly exceeds the achieved effects of hitherto known measures for increasing the sound attenuation.

It is noteworthy that the choice of the geometrical parameters according to the invention does not reduce the heat-insulating ability and load-bearing capacity of the building fitting at all.

According to a preferred embodiment of the invention, the ratio of the maximum slot lengths measured in the direction of the slot rows to the minimum spacing of two adjacent slots belonging to two adjacent rows of slits should be 3: 1 to 5: 1 and the sum of the minimum spacing between adjacent slits. and the spacing of the edge slits from the edge of the building fitting is 13.5% to 14.5% of the total width of the building fitting in the direction of the rows of slots. In these narrowed ranges of interrelationships, optimum properties of the building blocks are achieved.

In another particular embodiment of the invention, the transverse apertures of the slit have a rectangular or rhomboidal cross section with rounded corners, or alternatively may have an oval or elliptical cross section.

It is also possible for the cross-section of the transverse passages of the slits to be in the form of flat isosceles triangles with rounded corners whose base extends in the longitudinal direction of the individual rows of slits.

According to a further preferred embodiment, the individual slits of the triangular cross-section can be alternately oriented to opposite sides in one row of slots.

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With all these particular embodiments of the building fitting according to the invention, the aforementioned improvement in the soundproofing properties of the fitting is achieved, while the thermal resistance or load-bearing capacity of the fitting is not reduced.

The thermal resistance values enhancing the thermal insulating properties of the fitting can be further increased if, according to a further advantageous feature of the invention, at least one of the rows of transverse slits is curved symmetrically to the longitudinal axis of the fitting or

4 of the building fitting, the slot intersected by the longitudinal axis of the building fitting is broken at this point of intersection.

This solution results in a symmetrical and highly load-bearing arrangement, in particular if the curved or inclined rows are located in the region of the front ends of the building fitting, in which the rows of slots are to be curved or angled in the opposite direction.

In all of these particular embodiments, the transverse slots may be disposed in two adjacent rows with respect to each other, with the extreme slits of each second row being half the length of the normal slot length.

All of the above-mentioned advantageous results can be achieved with building blocks or blocks of conventional materials, such as concrete or aerated concrete or lime sandstone material, with the best results being obtained with burnt clay building blocks.

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Examples of a building fitting according to the invention are shown in the drawing, where FIG. 1 is a plan view of a transverse perforated building fitting in a first exemplary embodiment; FIG. 2 is a plan view of a quarter of a perforated building fitting in a second exemplary embodiment; and FIG. 3 are plan views of other possible transverse perforated fittings, each showing a quarter of the fittings.

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Fig. 1 illustrates a transversely perforated building block 1 having a width B and made of any material used for making such blocks, for example, baked clay, concrete, aerated concrete or the like, and its

The cross-section essentially corresponds to conventional building blocks of this type.

The transverse punched building fitting 1 is provided with an array of elongated vertically oriented slots 2 extending through the entire height of the fitting 1 perpendicular to its receiving surfaces having a length L and arranged in rows 3 extending perpendicular to the longitudinal axis of the building fitting 1a. longitudinal axis in a row.

In this first embodiment, the slots 2 have a rectangular cross-section with rounded corners.

In this description, the length L of the slot 2 is still considered the maximum length of the slot 2, measured at its longest point in the direction of the rows 3 of the slots 2.

The slots 2 of one row 3 are separated from each other and from the edge of the building fitting 1 by solid bridges and are spaced from one another or from the edge of the building fitting at a distance X which always expresses the smallest distance between two adjacent slots 2. the slots 2 and the edge of the building fitting 7, measured in the direction of the rows 3 of the slots 2. The spacings X of the slots 2 are substantially the same, while the spacings of the outer slots 2 from the edges of the fitting 1 can be selected according to the production process requirements. These basic sizes of the mutual spacing X of the slots 2 can be distinguished.

All adjacent slots 2 of two different rows 3 are spaced D apart from each other, which represents the smallest spacing between the two slots 2.

In this first exemplary embodiment, the slots 2 extend in the region of both front ends of the building fitting 1 in a curved shape, symmetrical to the longitudinal axis of the building fitting 7, while in the

In the central part of the building fitting between its two front regions, the individual rows 3 of the slots 2 are straight.

The curvature of these outer rows 3 of the slots 2 is opposite to the curvature of the rows 3 of the slots 2 at one front end of the building fitting 1.

The transversely punched building fitting 1 according to the invention is further provided with the usual recesses 5 on its contact walls 5. The slots 2 'arranged in the region around these recesses 5 have a shorter length by the depth of the recesses 5 compared to the other slots 2 of the building fitting 7.

The ratio of the length L of the slots 2 to the minimum distance D relative to each other between adjacent slots 2 belonging to two adjacent rows 3 in the illustrated embodiment is 4: 1. The sum of all spacings X between adjacent slots 2 measured in the direction of row 3 slits 2, between the end slot 2 and the edge of the building fitting 2 in this exemplary embodiment is 13.6% of the overall width B of the building fitting 1.

However, according to the results of the tests carried out, it is also possible that the ratio between the maximum length L of the slots 2 measured in the direction of the rows 3 of the slots 2 to the minimum distance D of the slots 2 in two adjacent rows 3 can range from 1: 1 to 6: 1. in particular from 3: 1 to 5: 1, wherein the sum of the minimum spacings X between adjacent slots in one row 3 and between the outer slot 2 and the edge of the building fitting 6 should be in the range of 12% to 18%, in particular 13.5 % to 14.5% of the overall width B of the building fitting 1, measured in the direction of the rows of the 3 fitting 1.

Only in these ranges of relationships between the slots 2 of the building fitting 1 can a surprising increase in the sound insulation and damping properties of the building fittings 1 be achieved at

-7 while maintaining the thermal insulating properties and bearing capacity and strength of the building fitting 1.

Fig. 2 shows a second exemplary embodiment of a building fitting 1 according to the invention provided with slits 2 of a triangular cross-section with rounded corners. The slots 2 in adjacent rows are offset relative to each other, with the extreme slot 2 of each second row 3 being half the width of the other slots 2 of row 3.

The basic geometrical shape of these slots 2 is a flat isosceles triangle whose base extends in the direction of the rows 3. The slots 2 arranged in a row 3 can also be oriented alternately on opposite sides.

Fig. 3 finally shows a number of other possible forms of a transversely perforated building fitting 1 according to the invention, which may be provided, for example, with elliptical slots in a symmetrically offset arrangement (FIG. 3a), rhomboid slots in a offset arrangement (FIG. 3b); in individual adjacent rows 3 facing each other, these rows 3 being inclined (Fig. 3c), or by rectangular slots without rounded corners arranged opposite to each other in adjacent rows 3. (Fig. 3d) or arranged in adjacent rows 3 with respect to each other ( Fig. 3e).

The inclined rows 3 of the slots of FIG. 3c extend at a mutually opposite inclination in the region of the front walls of the building fitting 1, while in the middle area of the building fitting 1, the rows of slots 3 run in a straight line and perpendicular to the longitudinal axis of the building fitting 1.

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The exemplary embodiments of a building fitting 1 according to the invention shown in the drawings represent only some of the possible embodiments and different combinations of slot shapes and their row arrangement; in order to achieve the intended effect, it is only necessary that the ratio of the slot lengths to the spacing of adjacent slits belonging to two adjacent rows is in the range of 1: 1 to 6: 1 and that

The sum of all X spacing of adjacent slits in one row was from% to 18% of the overall width of the building fitting.

Claims (12)

1. A transverse perforated fitting with elongated intersecting slots arranged side-by-side in rows extending side by side, characterized in that the ratio of the maximum length (L) of the slots (2) measured in the direction of the rows (3) of the slots / 2 /, the minimum spacing (D) of two adjacent slots (2) belonging to two adjacent rows (3) is 1: 1 to 6: 1 and the sum of the minimum spacing (X) of two adjacent slots (2) in one row (3), measured in the direction of the row (3) and the extreme slot (2) from the edge of the building fitting (1) is 12% to 18% of the width (B) of the building fitting (1) in the direction of the row (3). Transverse perforated fitting according to Claim 1, characterized in that the ratio of the maximum length (L) of the slots (2) measured in the direction of the rows (3) of the slots 121 to the minimum distance (D) of two adjacent slits 121 belonging to it. to two adjacent rows (3) is 3: 1 to 5: 1. Transverse perforated fitting according to 1 and 2, characterized in that the sum of the minimum spacings (X) of two adjacent slots (2) in one row (3), measured in one row (3), and the extreme slot (2) from the edge of the building fitting (1) is 13.5% to 14.5% of the width (B) of the building fitting (1) in the direction of the rows (3) of the slits 121. Transverse perforated fitting according to 11 to 3, characterized in that the slots (2) have a rectangular or rhomboidal cross-section with in particular rounded corners. 5. The transverse punched fitting according to -hndnv 1 to 3, having an elliptical cross-section. characterized in that the slots (2) have an oval or Transverse perforated fitting according to any one of Claims 1 to 3, characterized in that the slots (2) have the shape of flat isosceles triangles with rounded corners, the base of which is disposed in the direction of the axis of the row (3). Transverse perforated fitting according to Claim 6, characterized in that the slots (2) with a triangular cross-section, arranged in one row in succession, are oriented alternately on opposite sides. 8. The transverse perforated fitting of claim 1, wherein at least one of the rows (3) of the slots (2) is curved symmetrically to the longitudinal axis of the building fitting (1). Transverse perforated fitting according to items 1 to 7, characterized in that at least one of the rows (3) of the slots (2) is inclined symmetrically to the longitudinal axis of the building fitting (1), wherein the slot (2) intersects the longitudinal the axis of the building fitting (1) is kinked in the region of this longitudinal axis. Transverse perforated fitting according to Claims 8 and 9, characterized in that the curved or inclined rows (3) of the slots 121 are arranged in areas of both the front ends of the building fitting (1) and the row (3) located in the regions opposite each other. 1 / are curved or inclined to one another. VA Transverse perforated fitting according to Bottles 1 to 10, characterized in that the slits 121 in the two adjacent rows (3) are arranged offset from each other, the outer slots (2 '7 of each second row (3) having a length equal to half the length). (L) other slits 121. T * in G o / 4 - U Ό 12. The transverse profile according to items 1 to 11, characterized in that it is lime-sand, concrete or gas-concrete, or of clay.