WO2008138377A1

WO2008138377A1 - Set of building elements with elements of polypropylene

Info

Publication number: WO2008138377A1
Application number: PCT/EP2007/004277
Authority: WO
Inventors: Hugo Leeb; John Herbert Haritos
Original assignee: Hugo Leeb; John Herbert Haritos
Priority date: 2007-05-14
Filing date: 2007-05-14
Publication date: 2008-11-20
Also published as: TW200912102A

Abstract

Expanded polypropylene EPP with a density of the moulded part of approximately 55 kg/mm<SUP>3</SUP> is proposed as the material for building elements of a set of building elements and for toy figures, since this material has been recognized as being optimum for the purpose. Where they are building blocks (1, 2), the building elements are bodies which, in their basic form, can be joined to one another by abutting face to face and have cavities opening out on these faces, such as undercut grooves (11) or round channels (16), into which connecting bodies (3, 4) that engage in adjacent building elements on both sides can be introduced. The set of building elements therefore also comprises the associated connecting bodies, which may likewise consist of EPP, but also of Styropor, other plastic or metal. An especially favourable shaping for the building elements is described. The material of the building elements allows all common methods of working, such as sawing, screwing, drilling, painting, covering, coating, etc. By applying a nonwoven, various forms of outer appearance can be created. The building elements are distinguished by their light weight, stability and variable use, allowing rapid assembly and disassembly. Different sizes, shapes, thicknesses and colours may be provided.

Description

Set of components with elements made of polypropylene

The invention relates to a set of components with components made of polypropylene for the manufacture of spatial structures, namely in particular building blocks, building block fasteners and toy figures. Polypropylene members are known in the art (e.g., DE 2150314 A). However, the polypropylene is not specified. The known components also do not serve the creation of structures such as buildings.

There is a need for components that are light in weight and easy to mount. As examples of sectors where this need is clear, may be mentioned the house construction, the interior design, the decoration, the scenery construction and the exhibition. Especially for emergency shelters and "flying structures" and for many other construction measures would be lightweight and easy to assemble and dismantle component sets desirable, so far is essentially used wood. Furthermore, there is an urgent need for building materials with good thermal and acoustic insulation. Finally, gaming systems and toy figures, for example as equipment in kindergartens, are mentioned. These include, for example, also assemblable house, landscape, doll or toy machine components.

The invention is a set of components or toy figures are to be created, which are lightweight and therefore easy to transport, are mechanically resistant and can be easily assembled in case of need well and by laymen and also have ideal insulation properties.

This is achieved according to a first aspect of the invention in that the polypropylene is an expanded, so foamed polypropylene (EPP) with a molding density of at least 40 kg / m ³ and preferably in the range of 45 to 70 kg / m ³ lying. This provides the required strength and dimensional stability, which is particularly useful for components such as building blocks, and the weight of the elements can be kept very low, so that components of a reasonable size can be raised and held by a single person with one hand. In contrast to polystyrene, the EPP is impact-resistant and hardly sensitive to dot pressure. Particularly preferred is EPP with at least 50 kg / m ³ , in particular with 55 kg / m ³ , since at this density after casting no appreciable shrinkage of the component takes place and thus more easily constant sizes can be produced, while at the lower densities, even if they give sufficient strength, yet one Volume shrinkage occurs, which is not constant and therefore requires a re-sorting of the products. An additional advantage is the good thermal insulation of the material, as a result of which buildings constructed with it offer advantages especially in climatically extreme areas, but also in climatically temperate areas, where considerable efforts are made to save heating and cooling energy. Thus, when using the devices according to the invention living rooms with 80 m ² with 1000 watts and living rooms with 18 m ² with 60 watts are sufficiently heated. To further improve sound insulation, the components according to a special Schallschluck- execution have a rippled or provided with knobs or the like surface, so that the produced wall can reflect the sound only broken.

As far as a kit for erecting spatial structures such as walls, scenes, etc. is concerned, according to a second aspect of the invention, at least a part of the components have the characteristic that the components are flush-fitting surfaces surface-to-surface having cavities opening on these surfaces , in which mutually adjacent components on both sides engaging connecting body can be introduced. The bodies are in the simplest case parallelepipeds with rectangular outer surfaces, but a kit may also include arched structures, corner joints, angled elements, columns, etc. Apart from EPP, other materials are also suitable for these components; preferred alternatives are foamed polystyrene, which, however, has a lower impact resistance than EPP or gypsum granules bound by adhesive. The connecting bodies may also be partially made of expanded polypropylene having a molded density of at least 40 kg / m ^3, and preferably from 50 to 70 kg / m ³ , which can be easily dimensioned with sufficient strength for this function, but may also be one-third of that Costs can be made of polystyrene, which has sufficient strength for this use and there is exposed to any point pressure or shock, or may partially consist of unexpanded plastic or metal.

As areas on which the kits can be used with particular advantage, the simple construction, interior design, energy-saving construction, etc. have been mentioned, but there is also the Pontonbrückenbau both for the disaster and for the military Commitment.

In the walls produced from the kits according to the invention, etc. can be installed without special expertise electrical and water pipes, as can be provided in the components as cable ducts usable cavities. Drainpipes are installed in prefabricated components, which are provided with 10% inclined channels can, and installation items such as cisterns, for example made of PVC can be produced integrated with the device.

In particular, for connecting adjacent components is preferred for reasons of on the one hand the structural stability and on the other hand, the possibility of rapid assembly and disassembly, a structure in which the cavities and the connecting body dovetail-like engagement structures, wherein the cavities are rectilinear V-shaped grooves whose V-vertex below Forming an open gap along the contact surface extends whose V-legs are directed into the interior of the device strip or rail-shaped cavities and whose at least one end opens V-shaped on one of the outer surfaces of the device; and the connecting bodies are in cross-section cross-shaped prisms, which, divided in their longitudinal direction, identify two V-shaped halves whose cross-section is complementary to the V-shaped grooves. These - preferably made of EPP or Styrofoam - cross-prisms intervene on both sides in the corresponding V-grooves, whereby the two - in particular cuboidal - components are largely rigid, but releasably connected to each other under mutual surface contact, namely solvable insofar as they can be separated by pulling one of the components up or down. For connecting superimposed components connecting elements can be used, for which the cavities are inwardly directed channels from an outer surface of the component, while the connecting bodies are bars whose outer dimensions are complementary to the inner dimensions of the channels. Preferably, the connecting bodies are round rods and have the channels on the diameter of the rods matched, projecting towards the channel projections so that is ensured by small elastic compression of the projections a tight fit of the rods, which are in particular pipes. The inwardly projecting projections in the channel can also conically taper the resulting inner diameter of the channel cavity in order to facilitate the insertion of the round rods.

In the channels for the rods and rod-shaped parts of wall anchoring elements can be used, which further comprise, for example, a mounting plate, which can be attached in particular to the ceiling or floor, in the case of a 90 ° twisted mounting but also on a vertical wall. This makes it possible to anchor the structures erected from the structural elements and to stabilize them, for example, against wind power.

A preferred embodiment of the particular cuboidal components is that the cavities extend straight through the individual component from a first outer surface to an opposite second outer surface, in the course of their extension Have constrictions that limit the insertion of the respective connecting body, and all in a direction that is parallel to two opposite outer surfaces of the cuboid in each spatial direction, extend. The constrictions serve to limit the insertion depth of the connecting body, so the bars or prisms, and to prevent their slipping to lower-lying components. The channels can also have a limited depth. Through channels but lead to a certain material savings. The ducts can also be used to carry electrical or water installations, so you can install electrical outlets, switches, lights, water inlets and outlets, etc. anywhere

In particular, in the construction of houses or walls and walls, the channels or additional introduced holes or other continuous cavities, which may also be horizontal, are filled with concrete, optionally after drawing rods to achieve highly stable structures, at the same time in high degree of heat and soundproof. The fluidly poured concrete breaks down in the cavities, forming a lattice or skeleton that gives the wall stability and weight-bearing capacity.

When talking about "side by side" and "on top of each other", these are only illustrations, which probably also correspond to the usual mounting direction. Of course, the components described can also be mounted so that the prism-shaped connecting links connect superimposed and the bars adjacent components.

The system of the component set can be optimally adapted to individual requirements. In any case, the components are suitable for a variety of applications whenever an arrangement of stable walls is to be created quickly and simply. The special material makes the products even more valuable in terms of climate and the environment. It is also very versatile, e.g. by sawing, screwing, drilling, brushing, wallpapering, filling, etc., which further enhances the versatility.

The production of existing EPP components or toy figures can be carried out according to the invention so that one brings a granules of expanded polypropylene by pressure in a mold for implosion and thereby compacted.

Further details, advantages and developments of the invention will become apparent from the following description of preferred embodiments with reference to the drawings. Show it:

Fig. 1 in perspective view, parts of a kit with two components and with Connecting bodies;

2 shows one of the components in perspective view; FIG. 3 is a plan view of a modified embodiment of the component of FIG. 2; FIG. Fig. 4 shows a modified embodiment of the other in Fig. 1 with illustrated component in

Top view;

5 shows a perspective view of a cross-shaped connecting body. 6 shows a perspective view of a tubular connecting body; 7 shows a terminating element with possibilities for connecting installations; 8 shows a cross section through a channel in one of the components, in a sectional plane VIII-

VIII in Fig. 3; 9 shows a cross section through a channel in one of the components, in a sectional plane IX-DC in FIG. 4; Fig. 10 perspective views, on the one hand ready for use and on the other hand pulled apart and partially cut, an additional part of the kit; 11 is a perspective view of another accessory of the kit; Fig. 12 is a plan view of a device with a slightly modified design; FIG. 13 shows two corner connecting elements forming a wall corner; FIG.

14 shows two interconnected single-row arch elements with the outline of a circular ring segment;

FIG. 15 shows a serpentine line constructed from different arch elements; FIG. 16 shows a top view of an oblique connection component;

17 is a plan view of a wall corner with a rounding formed therein from an arc element and two oblique connection components.

Fig. 18 is a top view and front view of a vertical arc component;

Fig. 19 in perspective and in a central cross section, a component in the form of a column.

Fig. 1 shows elements of a kit for rapid erection and also dismantling of stable walls, as it takes place, for example, in the theater, for the fair, for the construction of shelters in disaster areas, etc. Basic elements are two "blocks" 1 and 2 designated cuboidal components that, often joined together, form the actual wall. For their cohesion serve connecting body, namely a cross-sectionally isosceles cross-shaped prism body, which is referred to as a cross connector 3, and tubular connector. 4 The building blocks 1 and 2 and the cross connectors 3 are made of expanded, that is foamed polypropylene, commonly referred to as "EPP" for short, with a bulk density or molding density of 55 kg / m ³ . At a density below 40 kg / m ³ , the material properties are unfavorable, at above the specified value of increased density increases the cost of materials unnecessarily and eventually the weight. One aspect of the production is the shrinkage of the material after casting, when the molding density is too low, in particular less than 50 kg / m ³ . Although the strength is then still sufficient, but irregular deviations occur, which can be avoided by the slightly higher mold weight. The cross connectors can also be made of polystyrene. The specified EPP has a high compressive strength and compression hardness, a tensile strength in the range of 750 to 800 kPa at an elongation at break of about 20%, a temperature resistance of -40 ° C to +50 ⁰ C and a burning performance of 42 mm / min with limited Flammability, and a water absorption under 1.1 vol% after 1 day. The thermal conductivity is 0.04 W / mK. From this data results the excellent suitability of the material for many construction purposes. The production of molded parts from this material is carried out by a special method so that it brings a granules of expanded polypropylene by pressure in a mold for implosion and thereby compacted. The material can still be added pigments to produce, for example, white, brown, black or otherwise colored blocks.

The blocks can be provided in different sizes, but also in a unit size. In the example described, which gives a favorable relationship between on the one hand the construction diversity and on the other hand, the production investment and logistics costs, the blocks 1 and 2 are offered with the following dimensions: height 330 mm, depth 300 mm, length of the block 1: 450 mm, and the block 2: 300 mm. The series may conveniently be supplemented by blocks of 150 mm depth and 150 mm, 600 mm and 750 mm in length. However, these are only dimensions, for example, but in any case meet the requirements of the dimensional stability and strength of conventional structures.

The cross connectors 3 can, as described, made of the same material as the blocks 1 and 2 or from another sufficiently strong material. They have in plan a transverse, oblique cross-configuration with four wings 8 and with rounded edges in the throats between the wings 8, as well as with a core body 9, from which the wings 8 go out. Adjacent wings 8 include a right angle, opposite wings 8 have a common radial or median plane. The cross connector 3 must have sufficient strength, to absorb the tensile forces occurring between the blocks 1, 2 and optionally also shear forces. In the example described, he has for this purpose an axial height of 50 mm, a thickness of the individual wings 8 of 23 mm and a core diameter of about 50 mm between opposite rounded grooves between adjacent wings. For the strength of the cross connector, it is sufficient to produce them from styrofoam, which can be produced with lower energy consumption and therefore more favorable in terms of cost and whose point pressure sensitivity in the cavities within the elements does not play a disadvantageous role.

The cross connectors 3 cooperate with V-shaped grooves 11, along the outer surfaces of the blocks 1 and 2, in the example described parallel to their respective cuboid edges between them in the middle of the square direction forming cuboid surface, so according to the selected terminology centered from above go down. The grooves 11 each consist of two in their longitudinal direction, ie from top to bottom, extending groove legs 12 and a common cavity forming them vertex space 13. In juxtaposition of two blocks 1 and / or 2 with their grooves 11 containing side surfaces are the grooves 11 together and together form a top-to-bottom extending cross-shaped channel into which the cross connector can be inserted from above or below ago, whereby the blocks are fixed, ie without significant play connected to each other in the lateral direction, wherein they are still mutually displaceable in the vertical direction , However, the sliding friction occurring in this case gives sufficient adhesion in the vertical direction, which prevents vertical displacements, especially as the wall constructed from the components sits down on the floor and, even if only a small weight of the wall pulls the components downwards.

In Fig. 1 of the cross connector 3 visible there is shown above the blocks 1 and 2 projecting to illustrate its function. In practical use, it is sunk in the blocks 1 and 2.

The connectors 4 are plastic tubes with a diameter of 50 mm and a wall thickness depending on the type of plastic, which must be sufficient for the tube to be able to absorb lateral forces acting on the wall. Solid rods are also suitable, for example from the EPP or Styrofoam of the building blocks and cross connectors. The connectors 4 are inserted into tubular channels 16 which extend in the vertical direction through the blocks 1 and 2. By the individual connector 4 inserted half in the lower and half in the upper block, these are connected to each other, namely when using only one connector against each other rotatable and when using two or more connectors non-rotatable.

The module 1 has six and the module 2 four rohrformige channels 16, which are each arranged in two rows. Narrower components, if present, may only be provided with the channels 16 in a single row. The single channel is basically cylindrical, but has along three circumferentially distributed generatrices extending, designed as webs or ribs projections 17 which project inwardly. The protrusion slightly increases from the surface of the module to the middle of the channel, so that between the three projections 17 a slightly conical bearing for the insertion of the connector 4 is formed

In Fig. 2, a special feature is indicated, namely an irregular mottling illustrated interruption of the otherwise smooth outer surface of the block 2 with nubs 18 projecting from the surface to a small piece and thereby exert a sound absorption function that complements the sound insulation of the element advantageous , Of course, instead of the irregular knobs, it is also possible to arrange regularly arranged knobs, furthermore ribs or hollows, which exert an echo-inhibiting and thus sound-absorbing function.

Reference is made to FIGS. 3 and 4, which show somewhat modified embodiments of the components 1 and 2, and the sectional views of FIGS. 8 and 9. The modification of the building blocks 1 and 2 consists firstly in that the grooves 11 continue in the form of double V-grooves 19, which are actually cross-sectioned channels, across the length of the building block between the rows of channels 16, the longer component 1 contains two double V-grooves 19 and the shorter component 2 contains a double V-groove 19. These grooves 19 simplify production, since the molds can be assembled from the same modules, and reduce the material consumption and the already low weight anyway. In the finished building they form channels e.g. for passing cables and pipes.

It can be seen from FIGS. 8 and 9 that two different embodiments are described for the modules 1 and 2 according to FIGS. 3 and 4, insofar as in the module 1, FIG. 3, the channels pass through and only in the middle of their extension Contain 21 in the form of an annular shoulder, which limits the insertion depth of the connector 4, so that without special attention from both sides connectors can be inserted and they can not sit slipped in their longitudinal direction in the channels. This also results in a rule for the length of the connector 4, which should have twice the value of the distance between the block surface and the constriction 21. In block 2, Fig. 4, however, as shown in FIG 9, instead of the constriction 21, a partition wall 22 is formed, the channel 16 in two of equal length Shares parts. The function of the connector 4 is the same, but allows the formation of Fig. 8 with the free space in the constriction 21, that here also other, longer elements can be inserted through, for. As stabilization rods, cables and air or water pipes.

Another difference between the embodiments is shown in Figure 4, namely, here is the V-shaped groove 11 in the course of their length, as can be seen from the outer boundary line. The cross connector can only be inserted to a given depth here, and can not be e.g. be pushed down with a rod from above between the blocks down.

The connectors 3 and 4 are shown in FIGS. 5 and 6, respectively.

Fig. 7 shows a supplementary element, namely a mounting module 25, which consists of a pipe section 26 of the same diameter as the connector 4, and a mounting plate 27 to which other installations can be screwed or which can be anchored to walls or walls itself. The mounting module 27 is inserted as needed in a free channel 16, as shown in Fig. 1 in the block 2. Inserted below and above in a channel 16 open from below or above, can be screwed with the help of the module 25, the erected wall to a lower or upper part of the building such as the floor, a ceiling or a permanently installed beams, causing the wall fixed and stabilized against lateral forces.

The kit can be extended by other additional parts, for example by - not shown - special sanitary blocks for sanitary installations, by screw connector for connecting the blocks with each other or with existing building structures in the case of expected higher loads such. Wind forces, or by a shown in Fig. 10 rolling element 30 for movable walls and a shown in Fig. 11 mounting aid 31 for erecting a wall with a door or a window.

The rolling element 30 comprises as an essential part a ball 34, which is rotatably held in a bearing 35 which sits at the lower end of a cylindrical piston 36. The piston 36 is in the form of an elongate plunger which slidably longitudinally dips into a tube 37 having the outer diameter of the connector 4 and which is long enough to extend upwardly at the restriction 21 or the partition wall 22 in one of the channels 16 of the lowest building block 1 or 2 can support the wall. The piston 36 slides with its upper, lower immersed portion on the inner surface of an inner pad 38, which is located in the upper part of the tube 37. This inner lining 38 partially reduces the inner diameter of the tube 37 and has at its lower edge a curve structure with, in the example shown, an upper and a lower "maximum". It can but also a larger number of maxima exist. The piston 36 has on its outer surface a nose-like cam follower 40, which comes to rest in one of the maxima 39 due to the weight of the wall. If it is at the highest maximum 39, then the rolling element 30 is practically sunk in the building block, and if it is in the lowest maximum 39, the wall is raised at the highest. Such rollability of the wall can be very useful, especially in theatrical scenery construction.

The mounting aid 31 is used when a door or lintel is to be mounted. It consists of a foot 44, a threaded tube 45 with internal thread, a threaded rod 46 which is screwed into the threaded tube 45 and the change in length of the aid 31 is used, and a support 47 which holds the part to be mounted until it sufficiently into the wall is integrated. The carrier 47 may also be rotatable about its vertical axis.

The cuboid blocks described with their connecting bodies represent an already very versatile and useful assortment. However, if - for example in stage and sliding block construction - even more diverse designs have to be built, then the set of components can be supplemented by many additional components, with FIGS 19 examples show.

Fig. 12 shows a device similar to the device of Fig. 3, but with the differences that the device is longer and thus also contains more double V-grooves 19 along its length, that at only one of its longitudinal ends does the V- shaped grooves are formed, while the other end is smooth, and that in the channels 16 not only three, but six web-like projections on the channel wall are formed.

Fig. 13 shows two corner building blocks 51 forming a corner which abut one another with a respective 45 ° inclined surface 52 in the manner shown. The inclined surface 52 gives the building blocks 51 the plan view of a rectangular trapezium. In FIG. 14 -herein using the example of single-row bricks - two arched bricks 54 are shown, for the erection of walls with a curved floor plan. The illustrated blocks 54 each cover an angle of 22.5 °. FIG. 15 shows a plan view of a wall constructed with arched bricks of the type shown in FIG. 14, but with two rows and curvatures of different radiusses. The dashed lines indicate the respective radius.

Figures 16 and 17 illustrate the layout and use of an angled connection block 56, shown in Figure 16 as a single row, shown in Figure 17 as a double row, by means of which an arc is placed in front of the corner 57 between two perpendicular abutting walls 58 can. Between the blocks 56 is shown in FIG. 17, one of the arc blocks 54th Fig. 18 again shows an arc, here designated 61, namely a vertical arc with a circular segment-shaped concave underside, which can be used as an archway or the like. For the connection of other components he has, like the previously described elements, the end of the V-shaped grooves and the upper side of the non-continuous channels in this case 16th

Finally, FIG. 19 shows an example of a pillar 63 belonging to the set of components, with a hexagonal pillar cross-section, as shown on an enlarged scale at the bottom in the figure. In addition to hexagonal columns, round, square or other columns are also possible. As the cross section shows, the channels 16 are formed in the column in that the column 63 consists of several sections, which are connected in the manner described by means of plugged into the channels 16 connector 4.

For toy figures, analogous structures can be chosen if they are combinable elements. For figures that are not to be assembled with other parts, the use of the indicated material is of use because it is very light, strong and stable and is well suited for children's hands.

Claims

claims

1. set of components with building block-like components (1, 2) made of polypropylene for producing space structures, characterized in that the polypropylene is an expanded polypropylene having a molding density of at least 40 kg / m ³ .

2. Set of components according to claim 1, characterized in that the molding density is in the range of 45 to 70 kg / m ³ .

3. set of components according to claim 2, characterized in that the molding density is at least 50 kg / m ³ .

4. set of components according to one of claims 1 to 3, characterized in that the component is a toy figure of expanded polypropylene with.

5. set of components with building block-like components (1, 2) made of polypropylene for the production of spatial structures, in particular according to one of claims 1 to 4, characterized in that at least a part of the building block-like components (1, 2) are face to face blunt adjoining body, the cavities (11, 16) which open out at these surfaces, into which connection bodies (3, 4) engaging on both sides in adjacent construction elements can be introduced.

6. set of components according to claim 5, characterized by connecting body (3) made of polypropylene with a molding density of at least 40 kg / m ³ and preferably in the range of 50 to 70 kg / m ³ lying.

7. set of components according to claim 5 or 6, characterized by connecting body (4) made of styrofoam, solid plastic or metal.

8. Set of components according to one of claims 5 to 7, characterized in that the cavities (11) and the connecting body (3) have dovetail-like engagement structures.

9. Set of components according to claim 8, characterized in that the cavities are rectilinear V-shaped grooves (11) whose V-vertex (13) extends to form an open gap along the contact surface, the V-leg (12) into the interior the device-oriented rail-shaped cavities are and whose at least one end opens V-shaped on one of the outer surfaces of the component (1. 2); and that the connecting bodies (3) in cross-section are cross-shaped prisms, which, divided in their longitudinal direction, identify two symmetrical V-shaped halves whose cross-section is complementary to the V-shaped grooves (11).

A set of components according to any one of claims 5 to 9, characterized in that the cavities are inwardly directed channels (16) from an outer surface of the component and the connecting bodies are rods (4) whose outer dimensions are complementary to the inner dimensions of the channels.

11. Set of components according to claim 10, characterized in that the connecting bodies are round rods (4) and the channels (16) matched to the diameter of the round rods, to the channel interior projecting projections (17).

12. The kit of components according to claim 5, characterized in that the cavities (11, 16) extend straight through the individual component (1, 2) from a first outer surface to an opposite second outer surface.

13. Component set according to claim 12, characterized in that the cavities (16) in the course of their extension constrictions (21) which limit the insertion of the respective connecting body (4).

14. Component set according to one of claims 5 to 13, characterized in that the components (1, 2) with respect to their outer surfaces are cuboidal and the cavities (11, 16) all in one direction, in each spatial direction parallel to two opposite outer surfaces is, extend.

15. Component set according to one of claims 5 to 14, characterized in that some the building elements (1, 2) are arc-shaped with respect to their ground plan and the cavities (11, 16) all extend in a direction parallel to two opposite outer surfaces.

16. Component set according to one of claims 5 to 15, characterized in that some of the components (1, 2) are prismatic with a trapezoidal base.

17 component set according to the dependent claims 9 and 10 to claim 14, characterized in that in a strand of rectilinearly joined components (1, 2) along a longitudinal center plane of the strand at regular intervals, the V-shaped cavities (11, 19) and rows of channels (16) along longitudinal planes each lying to one side between the longitudinal medial plane and the adjacent outer surface, the V-shaped cavities abutting each other in pairs to form crest cross-section vertices ,

18. Set of components according to one of claims 5 to 17, characterized in that at least a part of the components (1, 2) consist of styrofoam.

19. Set of components according to one of claims 5 to 17, characterized in that at least a part of the components (1, 2) consist of adhesive bound gypsum granules.

20. Component set according to one of claims 5 to 19, characterized by the building block-like components (1, 2) connectable holding elements (26, 27) with mounting means for attachment to fixed structures.

21 component set according to one of claims 1 to 20, characterized in that at least a part of the outer surfaces of the components has an uneven sound-absorbing structure (18).

22. A method for the manufacture of building block-like components made of polypropylene of the component set according to one of claims 1 to 17, characterized in that one Granules of expanded polypropylene by pressure in a mold to implosion brings and thereby compacted.