DE2625168B1 - SOUND INSULATION LINING MADE OF FOAM - Google Patents

Description

The invention relates to a sound-insulating lining made of foam with a uniform Relief structure consisting of square fields arranged one behind the other in which the Rectangular fields have several parallel ribs with intervening valleys and where the ribs and valleys of each field transversely to the ribs and valleys of all laterally adjacent fields get lost.

According to previous knowledge, an optimal sound insulation property is achieved if the Relief structure consists of a large number of evenly distributed pyramids. These so-called Pyramid insulation panels are, however, disadvantageous in terms of production technology, insofar as they are not loss-free Application of a center cut can be produced, as is the case, for example, with so-called studded panels the case is. Here the relief structure is offset on both sides to the middle section plane from the outside to be introduced deformation projections generated due to different compression. After leaving of the cutting area, the compression zones straighten up again, so that alternating troughs and protrusions occur. However, these studded panels only have a low sound-insulating effect.

From the article "Reflection-Free Spaces" by Dr Günther Kurtze, Mannheim, pp. 15 to 24, in "Heat, cold, sound" 6 (1961) 3, it is already known to achieve a surface that is as reflection-free as possible to arrange very slim, free-standing wedges rotated by 90 degrees against each other. A group of 3 wedges is combined to form a square field, so that at Another addition is a uniform, checkerboard-like relief structure made of rows one behind the other arranged square fields is created with several parallel ribs intermediate valleys. The ridges and valleys of each field run transversely to the ridges and valleys each of all adjacent fields. This sound insulation lining is disadvantageous in terms of production and allocation. Panels of this type cannot be cut without loss and therefore also not economically.

The object of the invention is to provide a generic sound insulation board in a simpler manner in terms of production, use advantageous design so that it can be cut without loss as well an optimal, d. H. Sound-insulating effect located in the area of the pyramid structure is achieved.

This object is achieved by the invention specified in claim 1.

The subclaims are advantageous developments of the subject matter of the invention.

As a result of this configuration, a generic sound insulation board is created that has optimal insulation properties possesses, but can nevertheless be produced without loss, for example in a continuous process. With The so-called center cut method can be used as an advantage. Each of the fields has several in parallel mutually extending ribs with intervening valleys in such a way that none of the valley-like shaped valleys continues freely; rather, are the ridges and valleys of every field aligned transversely to the ribs and valleys of all laterally adjacent fields. This leads to a Blocking of the valley ends in the interest of the desired optimal sound insulation effect. The respective cross-blocking from field to field also leads to an optically completely uniform arrangement over the entire area Surface plan. Due to the arrangement in which fields lying across corners alternate with each other Forming a negative-positive profile, two are mirror images of the same, in terms of their structure, they are not visually different from one another distinguishing plate halves produced completely loss-free This leads to an extremely inexpensive production, space-saving storage and appropriate shipping. The individual designed relatively large areas Panels can also be strung together in a largely non-disruptive manner in the overall picture. In particular for the sound-insulating effect, it is advantageous that the ribs of one field are convexly curved The crown edge and the ribs of the other field running transversely to it have a concave curved crown edge exhibit. With the same starting height, the rib saddles of one field are separated from the rib arch ridges the other ribs broken. This leads to an extremely even slat silhouette. The fact that the ribs also widen towards the base, can be relatively soft despite use Material a high level of stability can be achieved with a large rib height. One in this sense as well A favorable design measure is that the convexly curved apex edges have ribs have curved penetration edges. The ribs are rooted at different heights to the base of the block and to the next transverse rib of the neighboring field. The consideration of a continuous rib line on both side zones of each row of fields leads to

a most favorable dividing line or attachment line to neighboring panels, e.g. B. when laying these sound insulation panels. The use of such panels for purely decorative purposes or in combination Form is conceivable. With a correspondingly small field division, such panels are also suitable as anti-slip coverings.

The subject matter of the invention is hereinafter based on two graphically illustrated exemplary embodiments explained in more detail. It shows

F i g. 1 shows a perspective section of the sound insulation board according to the first embodiment,

FIG. 2 shows a section along line II-II in FIG. 1, 3 shows a section along line ΙΠ-ΙΙΙ in FIG. 1,

4 shows a section shown in perspective the sound insulation board according to the second exemplary embodiment, namely one half,

Fig. 5 after performing the central severing cut the other half of the soundproofing panel, which is detachable and mirror-inverted,

F i g. 6 shows a section along line VI-VI in FIG. 4 and FIG. 7 shows a section along line VII-VII in FIG. 4th

The section of the soundproofing panel shown in perspective comprises about a quarter of a standard size of 43 χ 43 cm. This chessboard-like divided area has 36 square individual fields F. For clarification, a correspondingly field-sized area is projected in a higher level and illustrated by hatching.

The sides of the square fields are marked with s . These fields F adjoin one another in rows and form several ribs 8 running parallel to one another. The ribs are separated from one another by deeply cutting, notch-like valleys 9.

The direction of the individual rib groups and valleys groups is such that the ribs 8 and valleys 9 of a field F run transversely to the ribs and valleys of all adjacent fields attached to the sides s.

The rib ends open with their entire cross-sectional width in the rib flank 8 'extending in front of transversely extending rib 8. This valleys 9 thus closing rib extends here in a continuous, of the field-base assignment corresponding ridge line xx (comp. Fig. 1), the can also be used as a dividing line. Its apex edge runs continuously undulating and essentially at the same level, corresponding to the lateral inlet of the ribs 8 of adjacent fields. Between each inflow point P this rib line falls in a conspicuously saddle-shaped or concave manner.

The width of Baer ribs 8 corresponds approximately to half the rib height, the minimum height of which is denoted by // and which increases slightly towards the inlet points. The rib flank angle alpha is approximately 13 °. The block thickness can vary considerably. It is based essentially on the height of the ribs to be produced, ie the required compression output volume for the structure-forming tools penetrating from the broad block surfaces.
The in F i g. 1 leads to a product that emphasizes more than the concave principle. The opposite, in mirror image, can easily be imagined from sectional figures 2 and 3. It consists of free-standing, also transversely blocked groups of ribs, whose Kerbtal-Grund runs essentially on a height level, as well as the above-mentioned apex. With this relief structure, the visual focus is on the convex principle.

The embodiment according to FIGS. 4 to 7 is a mixed structure in which rows of optically strongly concave relief structure delimited by continuous rib lines xx alternate with parallel rows of rib groups with a clearly convex relief structure. This mixed arrangement, in which the checkerboard-like division consisting of square fields F is not canceled, results, as can be seen from a comparison of FIGS. 4 and 5 it becomes clear, mirror-image sound-insulating panel halves optically completely identical, indistinguishable appearance. The relief structure of both halves therefore consists of square fields F arranged in rows one behind the other, which fields have several ribs 8 running parallel to one another with valleys in between

- ₀ 9, in such a way that on the one hand the ribs 8 and the valleys 9 of each field F are arranged transversely to the ribs 8 and valleys 9 of all laterally adjacent fields and on the other hand, corner fields alternately form the negative-positive profile.

The ribs 8 of one field F have a convexly curved apex edge 8 "and the ribs 8 of the other field F which run transversely thereto have a concavely curved apex edge 8 '". Here, too, the rib ends merge into one another in such a way that the ribs 8 having the convexly curved apex edge 8 ″ have strongly wavy or curved penetration edges K. Reference is made to FIG.

The relatively steeply sloping rib front edge 8 ″ ″ opens there in a higher level into the rib 8, which extends transversely in front of it, than the strongly notched base G of the lateral valleys 9.

The convexly curved ribs 8 widen towards the base surface.

The row of fields running in the cutting direction of the line VII-VII and laterally bounded by the continuous rib lines xx forms a trapezoidal block which fits into the corresponding trapezoidal cross-section of the longitudinal trough of the other half of the plate.

The neighboring fields or rows of fields are structured accordingly.

For this purpose 2 sheets of drawings

Claims (5)

Patent claims: 1. Sound-insulating lining made of foam with a uniform relief structure, which consists of square fields arranged in rows one behind the other, in which the square fields have several parallel ribs with intervening valleys and in which the ribs and valleys of each field are transverse to the ribs and valleys each of all laterally adjacent fields run, characterized in that the sound insulation lining is a sound insulation board with the relief structure on at least one broad side and that corner fields (F) alternately form a negative-positive profile. 2. Sound-insulating board according to claim 1, characterized in that the ribs (8) of one field have a convexly curved apex edge (8 ") and the ribs (8) of the other field (F) extending transversely thereto have a concavely curved apex edge (8") '") exhibit. 3. Sound insulation board according to claim 1, characterized in that the kovex arched ribs (8) widen towards the base. 4. Sound insulation board according to one of claims 1, 2 or 3, characterized in that the kovex arched apex edge (8 ") having ribs (8) have arched penetration edges (K). 5. Sound insulation board according to claim 1, characterized in that the two side zones of each row are formed by continuous rib lines (xx) .