DE10028299C2 - set of structural elements - Google Patents

Description

The invention relates to a set of components from wall blocks or from floor-to-ceiling plate elements of one or more wall or ceiling thicknesses for building walls and / or -cover that is made for a certain wall or ceiling thickness Main elements of a certain width, narrower lower part elements and possibly wider super-elements, whereby the Widths of the main and sub-elements are multiples of one largest common basic module are a and are reduced by a width of the main elements, in units of the largest common seed basic module a, is greater than one and a half times the Number of sub-elements.

The ratio of the width of the main elements reduced by a in units of a to the number of sub-elements different Widths are referred to below as the normalized width of the main element mentions. The invention thus relates to such a panel plate sets where the normalized width of the main elements te is greater than 1.5. The basic module a is through greatest common divisor of the latitudes of the main and lower elements given. The invention thus relates to such components ment rates in which at most two thirds of the related of dimension a possible sub-elements a, 2a, 3a,. , ., (n - 1) a (na = width of the main elements) are sub-elements. The component sets  are therefore appropriate to a certain extent "Thinned out".

A generic set of components is known for example from utility model DE 90 16 834 U1. The Bauele management kit of FIG. 1 comprises the elements of the widths of 1, 3, 6, 8, 17, 26, 35 in units of a basic module of 100 mm. Be considered the widest element as the main element in the sense of claim 1, its normalized width is 5 , 7th The selection of the sub-elements is therefore comparatively selective, which is associated with advantages in terms of storage and the manufacture of the component set. At the same time flexibility is given by a comparatively small grid dimension of 100 mm. In the example mentioned, the elements of the widths 17 can also be considered as main elements; the elements of widths 26 and 35 are then superordinate elements in the sense of claim 1. The normalized width of the main elements is then 4. Another generic set of components is known from the publication DE 198 36 171 A1. As particularly geous, a component set consisting of elements of widths 4 , 5 , 11 in units of a largest common basic module of 125 mm was recognized there, for example. In this case, the normalized width of the main elements 5 . This is also a specifically selected set of elements that, with a minimal number of sub-elements, achieves the greatest possible flexibility on a relatively small scale of 125 mm.

All the aforementioned generic component sets are ge mean that the manufacturing effort for this is considerable. For the latter example (DE 198 36 171 A1) are at for example, either three different devices  Manufacture of elements of three different widths provided. To reduce the effort, you could only featured a device for producing the widest elements be seen, the narrower elements by cutting of the wider elements. The disadvantages lie gene in the fact that under certain circumstances extensive editor and almost always a certain amount of unusable cut remains that are due to the Ma material waste and the disposal problem additional costs cause.

The present invention is based on the object the above-mentioned component sets develop that both the number of plate elements as well as their manufacturing costs can be kept low without that the high flexibility to achieve differ cher wall widths is limited.

For this purpose, the invention provides that the widths of the Sub-elements are set so that the widths of more than 50% of the sub-elements of different widths pair Add wisely to the width of the main elements. The sub Elements that meet this condition are as follows referred to as minor elements. Sub-elements whose width is ge corresponds exactly to half the width of the main elements basically viewed as secondary elements.

The invention has recognized that for the manufacture of the inventions Invention secondary elements essentially already the Her Position of elements of a width, namely the width of the Main elements, enough. Two secondary elements according to the invention can consist of a main element by a single element  vertical section. When producing the Secondary elements can be completely avoided and the cutting work is kept to a minimum.

The success of the invention is the greater, the more Unterele elements of different widths in pairs to the width of the Add main elements. Therefore, advantageously meet more than 60%, 80% or even all sub-elements of these Condition.

The greater the success of the invention, the greater the extent thins the component set on that by multiples of the bottom module a predetermined grid from the outset.

The component set can contain components from different wall or cover thicknesses. The invention relates to in this case at least on one of the parts of the component set, the elements of a certain wall or ceiling thickness affect. However, preferably all elements of the Component set the features of claim 1.

As names for the dimensions of wall blocks in the three spatial directions are the terms width, height and Wall thickness used. It should be noted that the wall width in the sense of this invention for wall blocks in many cases also as Wall length is called.

The rational creation of larger wall or ceiling to allow wide, the width of the main elements at least ten times, preferably fifteen or Twenty times the basic module a.  

It is an important property of the generic building blocks principles that by any combination of main and / or sub-elements based on multiples of the basic mo duls a given grid the creation of walls or Ceilings with any width in the grid from a certain Allow minimum wall width. So it occurs above this minimum wall width does not contain any wall slurry contained in the grid te more on that not with the help of the construction according to the invention elements set could be created. Such component sentences are referred to as "complete" from the minimum designated wall width. The minimum wall width can, for example correspond to the width of the main elements. In many It is sufficient if, for example, the two- Three or four times the width of the main elements speaks when creating smaller wall widths in the Practice doesn't matter. This applies regularly to blankets slabs or walls below 1.5 or 1.0 m.

The completeness of the achievable latitudes in the above ge mentioned meaning is in the generic table plate sets thereby causing the widths of the main and sub elements multiples of a largest common basic module a which corresponds to the desired grid dimension. A ver Improvement of this aspect of the invention is accomplished that at least two sub-elements and / or secondary elements ent hold, the widths of which are exactly one basic module a un differ. Preferably it can also be a group of Act sub-elements, the widths of which are each one Distinguish basic module a. One or more sol cher groups of pairs may be provided. Groups of lower elements whose widths differ by a act in such a way  the breadth from which a completeness of he targetable wall widths is achieved to reduce. Already two on the scale specified by the basic module beard elements already represent a complete one area without a gap. By using multiple of the like sub-elements emerge larger like that areas, thereby completeness overall Reachable from a comparatively small width is.

The width of the secondary elements should advantageously be a ge Do not fall below the minimum width, so that the widths the secondary elements do not deviate too much from one another. the This characteristic is based on the observation that the first the smaller secondary elements of any wall width tend to be needed more often. The feature mentioned therefore acts in such a way that secondary elements of different mush tend to be about the same frequency for creating any Wall widths can be used. It is also rather possible Lich, to create a balance, if once a side element certain width should be out of print.

The component set preferably comprises all elements the grid specified by the basic module a from a be agreed width range, the upper limit of which is not essential is less than 50% of the width of the main elements. Beson a width range of 40 to 47.5% is preferred Width of the main elements. The widths of the secondary elements are sol len on the one hand not too different from a width of 50% the main element width, so that the distance of all Minor elements from each other is small. On the other hand, has shown that the width range of 47.5 to 50% is dispensable  can be because already without the corresponding secondary elements Completeness in the range of achievable wall widths a sufficiently small wall width can be effected.

To get an optimal range of one through the Grundele ment a given grid to densely located secondary elements can be determined step by step as follows. First, the secondary element is determined, the width of which is possible As close as possible to a value of 45% of the width of the main elements te lies. This element has the width n (in units of a). It is then first checked whether the sentence that results from the Elements n, B - n, B (where B is the width of the main element mente), from a certain desired minimum wall width te is complete, d. H. whether from a combination These three elements cover every wall or ceiling width the basic module has a predetermined grid, which is larger than the minimum wall width. If not If this is the case, the next largest minor element becomes n + 1 together consulted his partner B - (n + 1) and again on full consistency checked. If this is not successful, will the selection area of the secondary elements, which is now two ne benelemente plus related partners includes by one shifted down. The corresponding sentence then consists of the Elements n - 1, n, B - n, B - (n - 1), B. completeness. If this is not the case becomes related to a related area continued from now three subsidiary elements plus partners. In general, the xth test step consists of x sub-steps. The first step is the completeness check of a Set that includes x neighboring sub-elements, their small stes corresponds to the secondary element n. The second step is the completeness check of a sentence, the x by one unit  includes down-shifted minor elements, d. H. the Secondary elements n - 1 to n + x - 2. The last substep concerns a sentence with the secondary elements n - (x - 1) to n the umpteenth step ended. The procedure is described in Au canceled at the moment in which a component set to be tested fulfills the required completeness requirement. On the ge named way can be an optimal component Determine the rate in which the desired flexibility with a minimum number of plate elements is reached.

The largest common basic module a can be 100 or 125 mm wear and thus the module of the octametric or the euro European module step. The is preferably largest common basic module a = 25 mm, which on the one hand a gradation on a much narrower scale is sufficient and on the other hand compatibility with both above module steps is maintained. At a largest common basic module of 25 mm can be the width of the Main elements preferably a multiple of a larger Ra dimension A, which is for example 100 or 125 mm. The width of the narrowest secondary element is also preferred a multiple of the grid dimension A. Completeness on the given by the grid dimension A. Scale with a correspondingly lower number of secondary elements ten can be achieved. Other subsidiary elements, which a full consistency on the by the largest common basic module a predetermined grid, could then as needed to be added. The secondary elements advantageously have te at least one corresponding to twice the grid dimension A. Width. With that in mind, it can be beneficial if it is the multiples of a basic module a in the sense of the claim  1 is a real multiple, so that an element with the width a is excluded from the outset.

To create large wall lengths easily and efficiently can, it can be advantageous to add elements with egg ner wider than that of the main elements. Such wide elements are in claim 1 as Inscribed over elements. However, they are for the success of the Invention is not essential, so the main elements too formed by the widest elements of the component set can be.

The invention is described below with reference to the a Zige drawing with the help of advantageous embodiments illustrated. It shows:

Fig. 1 is a cross-sectional view of a panel plate set according to the invention.

The following table lists a number of advantageous table plate sets according to the present invention. In column 1 , each individual sentence is labeled with a consecutive number. Column 2 specifies the largest common basic module a on which the main and secondary elements are based. Columns 3 and 4 show the widths of the main and secondary elements. The numbers in columns 2 to 4 are in mm. Column 5 gives the normalized width of the main elements, ie the width of the main elements reduced by a in units of a divided by the number of secondary elements. The value in column 6 indicates from which width, in units of the width B of the main element, the table plate set is completely on a scale given by multiples of the largest common basic module a. The secondary elements of a table plate set are wider than the minimum width specified in column 7 in units of the width B of the main element.

The features of the subject of the invention will follow discussed in detail using an example, the main elements based on a width of 600 mm. A is desired Plate set, which is complete from a width of 1200 mm is on a grid that by multiples of a basic module a of 25 mm is given. The plate plate sets No. 1 to 4 from The table fulfills this requirement, as explained below is tert.

The plate set No. 1 consists of a main element of the Width 600 mm and five secondary elements of widths 250 mm, 275 mm, 300 mm, 325 mm and 350 mm. As you can see, each two secondary elements by cutting one appropriately Main element are generated, for example. The elements 250 mm and 350 mm. The Ne which complements the width of the main element ben elements are arranged one above the other. Also the elements with a width of 300 mm are secondary elements as they add up with their peers to the width of the main elements. Fulfill all sub-elements listed in the table this condition and thus form secondary elements in the sense of this invention.

In units of the largest common basic module a of 25 mm, the plate element set No. 1 therefore consists of the main and secondary elements ( 13 , 14 , 16 , 17 , 30 ). It is understood that this table plate set in units of a is also encompassed by the invention for other values of the basic module a, for example 50 mm. The plate set No. 1 could contain, in addition to the listed secondary elements, further sub-elements, the complementary partners of which are not included in the width of the main elements, for example sub-elements with a width of 500 mm. It could also be provided over elements with a width that are larger than the main element width of 600 mm, for example. Elements of width 750 mm. It is pointed out that the values in columns 5 to 7 of the table for table plate sets were calculated which, in addition to the specified main and secondary elements, contain no further plate elements of this wall thickness.

Tafelplattensatz No. 1 consists of only five Nebenele elements, which form a single group of neighboring on the given by multiples of the basic module a neighboring plate elements. Although the narrowest secondary element is ten times as large as the basic module a, completeness in the range of achievable wall widths is already aimed at from a width of 750 mm, i.e. only a little more than the main element width (column 6 ). With a suitable combination of the main and secondary elements, the wall width of 750 mm and any wall width above can be produced in steps of 25 mm (775 mm, 800 mm, 825 mm,...).

The board set No. 1 is advantageous compared to board record sets of the prior art, since it is using a compared to the basic module broad main element, which for ra tional creation of larger wall widths advantageous and a number of five secondary elements, their widths are also great against the basic module a, completeness on the grid specified by multiples of the basic module a achieved from a width of 1.25 times the main element width.  

The number of the proposed sub-elements, here five, and the associated manufacturing, storage and organizational expenditure is expediently measured relative to the width of the main elements (reduced by a) in units of a; because with comparatively large main elements (in units of a), more secondary elements are necessary in order to achieve such flexibility. A suitable measurement for the flexibility of the component set relative to the effort is the normalized width of the main elements specified in column 5 . When comparing table plate sets with main elements of the same width, which are based on the same basic module a, the normalized width of the main elements is greater, the smaller the number of sub-elements provided. The larger the standardized width, the lower the manufacturing, storage and organizational effort in this case.

A look at Table 1 shows that plate set No. 2 at same flexibility a lower effort and thus Ko means savings compared to plate plate set no. 1. He differs from table plate set no. 1 only by Omit half-width elements of main elements (300 mm). So there are only four instead of five secondary elements here required. The secondary elements of the plate set No. 2 arise from the selection rule of claim 5, according to all possible secondary elements are included (250 mm, 275 mm), whose widths range from 40 to 47.5% of the main element width (240 to 285 mm).

As can be seen, the effort associated with the manufacture etc. for plate set No. 4 ( 8 , 9 , 15 , 16 , 24 ) a is just as small as for plate set No. 2, although here completeness is only from a width of 950 mm is achieved, which, however, is usually sufficient in practice.

Plate set no. 2 has the opposite of set no Advantage that all secondary elements are wider than 250 mm, d. H. 41% of the main element width. In contrast, they are Additional elements of the plate set no. 4 only wider than a third of the main element width. This results in, that the widths of the secondary elements of sentence No. 2 um maximal deviate at least 100 mm from each other, while this value at Set No. 4 is almost twice as large (175 mm). At the Er Any larger wall widths are used to set the secondary elements elements of sentence 2 tend to be used approximately equally often det, while in set number 4 the narrower elements are more common are needed. The use is about the same partial, because by cutting a main element in each case a larger and a smaller secondary element are created.

Advantages can also arise if secondary elements are one certain width are out of print; as an example he position of a wall with a width of 1025 mm. With help of plate set No. 4, this wall width can be seen through create different combinations, but in each in the case of additional elements with a width of 225 mm are required. If these are temporarily sold out, a wall of porridge can te 1025 mm not without cutting work on the part of the client to be created. When using the plate set No. 2 can be said wall width both by combination nation of three elements of width 250 mm with one element the width of 275 mm as well as by combining two elements width 350 mm with an element width 325 mm put. A wall with a width of 1025 mm can therefore be used  Create sentence no. 2 regardless of whether secondary elements are one certain width are currently out of stock.

On the other hand, plate element set No. 4 offers the advantage that it comprises plate elements (200 mm, 400 mm), their widths Are multiples of a larger grid dimension A = 100 mm. This can be advantageous because in practice grid dimensions of 100 mm (European system) or 125 mm (octametric sy stem) occur.

The plate set No. 3 contains all possible Ne ben elements whose widths range from 33 to 50% of Main element width are. This sentence includes a large Larger number of secondary elements, however, has the advantage that he already from a width of 200 mm, d. H. the width of the narrowest plate element, completely on the by diversity surface of the basic module is a predetermined grid.

In the following he will be explained using the plate element set No. 7, how an optimal selection of secondary elements can be achieved. First, it should be noted that with the help of the particularly preferred criterion mentioned in claim 5, six secondary elements would be selected, the widths of which would be in the range from 500 to 550 mm and 650 to 700 mm. Although with a main element width of 1200 mm and an underlying module of 25 mm this already represents a very favorable selection (standardized width 7.8 ), the effort can be reduced even further with the help of the following selection process.

First the element is determined, the width of which is 45% of the Main element width comes closest, in this case the element  the width 550 mm. The resulting Plattenele set of the three elements of widths 550 mm, 650 mm and 1200 mm, is now checked whether it min at least from the desired width, e.g. B. 2400 mm, completely is on a scale given by multiples of 25 mm. At first glance, this is not possible because the largest common divisor of the three plate elements 50 mm be and is twice the size of the desired module step. In the second step, the next largest minor is ment of the originally determined secondary element including its Partner involved, in this case the couple from Nebenele elements with the widths 575 mm and 625 mm. It turns out that the corresponding table plate set with four secondary elements only from a width of 3300 mm fully in terms of egg module of 25 mm. The present example assumes this from that a completeness, however, already from the Zweifa Chen the width of the main elements, i.e. 2400 mm, desired is. The mentioned plate set fulfills this criterion Not. The second sub-step of the second step provides that the secondary elements 550 mm and 575 mm by one unit be moved down. So it becomes a set of blackboard plates produces elements of widths 525 mm, 550 mm, 650 mm, 675 mm and 1200 mm. This table plate set is from one Width of 2100 mm completely on a multiple of 25 mm predetermined scale. So you get clearer Way to the optimal table plate set No. 7 of the table, the has only four instead of six secondary elements.

Most of the table plate sets listed in the table consist of a group of two or more pairs of Ne benelements, the widths of which are each a basic mo dul a distinguish. While this is beneficial in many cases,  but not necessary for the success of the invention, like the two exceptions, namely the plate plate sets No. 9 and 16.

Most of the table plate sets listed in the table meet the condition that the width of the main elements corresponds to at least ten times the basic module a. Also this characteristic is not necessary for the success of the Erfin as the table plate sets No. 15 to 18 illustrate.

Fig. 1 shows a panel set in cross-sectional view, the main elements 1 have a wall width of 750 mm. In Fig. 1 the wall width is plotted from top to bottom and the wall thickness from right to left. The Tafelplat set also includes all pairs of sub-elements within a range of one third to 50% of the main element width, which are on a given by multiples of the basic module a grid (250 mm, 275 mm, 300 mm, 325 mm, 350 mm , 375 mm). Furthermore, all Plattenelemen te 2 are included, which add up in pairs with the sub-elements mentioned to the width of the main elements 1 (500 mm, 475 mm, 450 mm, 425 mm, 400 mm). As can be seen from FIG. 1, all of these pairs of sub-elements can each be produced from a main element 1 with the aid of a single cut at corresponding positions 3 . The normalized width of the plate set shown is 2.6. From a width of 250 mm, ie the width of the narrowest sub-element, it is completely related to the grid dimension a. It also includes the three plate elements of widths 250 mm, 375 mm, 500 mm, which are multiples of the octametric module step of 125 mm. The width of the main elements 1 is thirty times the basic module a = 25 mm and six times the octametric grid dimension of 125 mm. The width of the narrowest sub-element is twice the octagonal grid dimension A.

Claims (9)

1. Set of components from wall blocks or from floor to ceiling plate elements of one or more wall or ceiling thicknesses for erecting building walls and / or ceilings, the elements for a certain wall or ceiling thickness from main elements ( 1 ) of a certain width and narrower lower elements ( 2 ) and possibly wider super-elements, the widths of the main and sub-elements each being multiples of a largest common basic module a and the width of the main elements reduced by a, measured in units of the largest common basic module a, being greater than one and a half times the number of Unterele elements of different widths, characterized in that the widths of more than 50% of the sub-elements ( 2 ) of different widths add in pairs to the width of the main elements ( 1 ). 2. plate set according to claim 1, characterized in that the width of the main elements ( 1 ) is at least ten times the basic module a. 3. plate set according to claim 1 or 2, characterized in that at least two sub-elements ( 2 ) are included, the widths of which differ by a basic module a. 4. plate set according to one of claims 1 to 3, characterized in that the widths of the complementary to the width of the main elements ( 1 ) sub-elements ( 2 ) at least 25%, preferably at least a third, preferably at least 40% of the width of the Main elements ( 1 ). 5. plate set according to claim 3 or 4, characterized in that the narrower sub-elements of all of the main elements ( 1 ) complementary pairs of sub-elements ( 2 ), a width in the range of 33 to 50%, preferably 40 to 47.5% of Have width of the main elements ( 1 ). 6. plate set according to one of claims 1 to 5, there characterized in that the basic module a in the range of 25 to 150 mm, preferably 25 to 50 mm and / or is a multiple of 25 mm. 7. plate set according to one of claims 1 to 6, characterized in that the width of the main elements ( 1 ) is a multiple of a grid dimension A, which is in the range from 100 to 150 mm. 8. plate set according to claim 7, characterized in that the width of the narrowest sub-element of all the complementary to the width of the main elements ( 1 ) pairs of sub-elements ( 2 ) is a multiple of the grid dimension A. 9. plate set according to one of claims 1 to 8, characterized in that the complementary to the width of the main elements ( 1 ) sub-elements ( 2 ) have at least one width corresponding to the double pitch A.