DE202014004150U1 - Magnetic holding system of flat support elements on a particular stationary surface - Google Patents

Abstract

A holding system made of flat support elements (1 and 2), which can be fixed to a particularly stationary surface, the arrangement having a first grid-shaped support element (2) which has recesses (3) which have holding devices (8) for holders (4) and a second Support element (1) rests on the stationary surface, characterized in that in the holding devices (8) holders (4) can be releasably fixed in a form-fitting manner according to the grid dimension and at least one permanent magnet (7) is provided on each holder (4), which is connected to the two support element (1) forms a magnetic, releasable frictional connection.

Description

The invention relates to a particular fixed surface, such as a wall, support structure or the like, festlegbares holding system for particular flat support elements on which more, especially flat, grid-shaped support elements using spacers or directly attached, wherein the recesses of the front support members holding devices represent, in which one or more holders cantilevered and releasably fixed, the positive connection is made by the size of the recess in relation to the size of the holder and the adhesion by magnetic force between the holder and the former, in particular flat support member comes to conditions.

A comparable holding system is already widely used in practice in a wide variety of embodiments, and thus belongs to the state of the art through obvious prior use.

For example, magnetic strips and walls are known as holders, wherein other magnetic or magnetizable trained objects or hooks are attached to these strips and walls, wherein the magnetic force forms the adhesion.

Shelf applications are furthermore known in which hollow cubes are at least partially magnetically or magnetizable in order to be magnetically supported on at least one magnetic or magnetizable wall plate.

Such a procedure in the holding process is the utility model DE 200 11 351 U1 in which a shelf arrangement with at least one shelf for carrying objects is characterized in that the shelf is provided with at least one holding plate which is at least partially magnetically or magnetizable formed on its wall facing side to at least one magnetizable or magnetic Wall plate to be worn magnetically on the wall. The shelf assembly is magnetically attached to a support member to carry articles.

There are also known as wall clamps as a holder, wherein two parallel legs of a U-shaped clamping profile form Halterstützflächen, between which can trap flat bottoms with a suitable strength. The wall clamping rail extends substantially over the entire length of the flat bottom and may include this on one side. Therefore, the flat bottom is used for mounting from the front into the rail and fixed by its own weight reliably non-positively and positively. The wall clamp rail can be fixed to stationary surfaces.

There are already known in terms of their function similar holding systems in which pieces of wood of different dimensions and optics are provided with magnets to allow them to adhere to magnetic or magnetizable trained objects. In this way, a small support element with low object support and magnetic strength, whereby the severity and size of the possible objects used is limited.

There are also known holding systems for flat support members, wherein a respective support member is cantilevered between the support support surfaces of one or more holders, as determined by the DE 10 2010 017 771 A1 is known. The holders are placed on a stationary surface.

Another holding system is through the DE 203 03 813 U1 known, wherein retaining elements are introduced for holding shelf elements in a clamping rail. On these retaining elements then the shelf elements are attached. The clamping rails are introduced as a profile in a wall surface, the holding elements are held by appropriate clamping parts in the profile.

The DE 20 2008 002 066 U1 represents a wall surface with a recessed profile device, which has an opening to a wall side, can be introduced into the holding elements. A nose, which is mounted on the opposite inside of the profile holds the holding elements.

Another arrangement for attaching shelves to a fixed surface is the DE 199 09 440 C1 wherein a, to be fastened to a wall or clamped between a floor and a ceiling, profile body with parallel legs connected by a base serves as a holder element for a shelf.

A disadvantage of the illustrated holding systems and arrangements for cantilevered support elements is in principle the reduction to either flexibility and variability or stability to evaluate. Both points in connection with an appealing look are not served. In the majority of additional parts to increase stability and fixability are necessary because to make the support elements for laymen solvable and thus variable, the majority of existing fixtures and arrangements for cantilevered support elements more complex, less elegant tools such as wedges needed. Also one Adaptation to different loads is hardly given. Furthermore, although a change in the height of the shelves and support elements is partly feasible, position and length of the shelves and other support elements but only very limited variable. Furthermore, in many of the described arrangements, an exact position and orientation of the attached support elements is not given sufficiently. A large area, only flat adhesion of a shelf element to a base is only approximately sustainable if a large attraction is present. At the same time, this attraction prevents a comfortable change of position and an exactly horizontal fixation of the elements seems difficult. In addition, the majority of existing fixtures require optically unattractive bores or cantilevered parts, as particularly in the DE 81 23 758 the case is. Overall, none of the illustrated holding devices and arrangements for cantilevered support elements both form and adhesion is maintained.

Against this background, the invention has for its object to provide a support system for support elements, which can be flexibly adapted to a variety of purposes and thus guarantees a very high variability. This not only includes different positions of the support elements, but also an adaptation of the support elements on the objects provided for this purpose. Different loads should be able to be carried. Even laymen should be able to vary the support elements tool-free and fast. In the connection between the holder and holder device and base not only form but also adhesion is granted.

This object is achieved with a device according to the features of claim 1. The further embodiment of the invention can be found in the dependent claims.

According to the invention, therefore, a holding system is provided which has a base to be fixed to a fixed surface, for example, a wall surface or a supporting structure base on which the holder can be releasably fixed in any positions and distances according to a fixed pitch. In this case, only the fixing of the plate-shaped base to the intended surface is necessary, wherein the holders are easily and detachably connected to the base. The position and number of holders can be varied as often as desired without tools, and also by laypersons, due to their easy solubility. Furthermore, structurally identical or different holders can be combined with one another in order to allow in this way a quick adaptation to the respective load and use of the support element with very little effort. The holders are introduced into a grid-like holding element, wherein the size of the recesses in the grid approximately or exactly corresponds to the size of the holder, whereby the positive locking is ensured on all sides or at least in one axis of the holder, as long as desired. Otherwise, some dimensions can also be chosen deliberately different, to allow greater mobility of the holder. The holders used may have any shape, be hollow or made of solid material, and be chamfered at its tip to facilitate their introduction into the holding element in this way. The fit between holder and holder device can vary. The holder should thereby have minimally smaller external dimensions than the corresponding internal dimensions of the recesses in the grid-like holding element, or have at most the same dimensions. The convenience in inserting the holders in the recesses in the grid-like holding element, which represent the holding devices, increases with increasing difference between external dimensions of the holder and inside dimension of the recesses, while the stability and load capacity of the introduced holder is improved in the reverse direction. The grid-like support member may be directly attached to the plate-shaped base which is fixed to the surface provided, or it may, if desired, spacers between plate-shaped base and grid-like support member are mounted. The adhesion is ensured by the magnetic force between the base and the holder end, while the positive locking is guaranteed by the ratio of the outer dimensions of the holder and the internal dimensions of the recesses in the holding element to all sides of the holder out. In addition, the connection of the holder with the aid of magnets with the basis of the invention proves to be particularly wear-resistant and cost-effective.

A particularly advantageous embodiment of the invention is realized that can be selected by the arbitrary size of the support elements depending on their length and height, and their planned support weight a corresponding number and version of the required holder for these support elements. It is not necessary that the holder of the support elements have a uniform distance from one another or are dimensioned consistently. As desired, the holders can also have a greater height in their projection than the support element itself, in order to additionally use the supernatant of the holder as a suspension can.

It is also particularly advantageous that in the distribution of support elements as shelves and cantilevered hook brackets must not be taken to ensure uniformity in position and weight, since the base and the grid-like support member are already constructed so that a sufficient stability is ensured by form and adhesion.

Furthermore, it is particularly advantageous that the basis of the invention in combination with the grid-like holding element already offers such possibilities for suspending various objects with handles and curves, whereby attachment of holders both as a hook and as a holder for support elements such as shelves not mandatory is, but the invention can be used completely without support elements on its front, for example by the suspension of objects such as scarves through the recesses in the grid-like support member.

Another advantage of the invention is the possible use of the rear base, which is attached to a stationary surface, as a magnetic wall. If the base slightly larger length and width dimensions than the grid-like holding element, which is usually mounted spatially in front of the base, the rear wall can be on the sides and up and down by their magnetic attraction in addition as a suspension of magnetic or magnetizable trained objects such as jewelry, use clothing elements such as belts or the like.

Furthermore, it is particularly advantageous that the optics and use of the invention can be varied as often as desired even by laymen without tools, without a change in the base suspension is necessary. The appearance and use of the invention can be easily adapted to the consumer's wishes with very little effort without the original suspension of the base on a stationary surface having to be adapted or changed to the changed payload and usage.

Another advantage of the invention is the ability to attach shelves on the holders can. Since these are not clamped, but only rest on holders, their strength can be varied easily. The shelves can be mounted without additional installation on the holders and carry your burden on the holder and ultimately the base. For this reason, it is also possible to use shelves which the consumer already has in stock, as a result of which he is not bound by the offer of shelves exactly fitting this invention. As an additional stabilization, however, it is an advantage to make the shelves and holders at the contact points also magnetic and magnetizable to form a unit can. Another embodiment provides outstanding holder-like pins on a shelf, whereby the shelf can be inserted equivalent to the holders directly into the grid-like support element and it requires no further support points. Alternatively, the board can also have grooves or milling, which install the board form-fitting on the holders.

An advantageous further development of the invention provides for the holders, which are inserted into the grid-shaped support element, to be shaped or manufactured in such a way that their center of gravity is designed to be favorable. This means that the center of gravity is constructed away from the center of the holder in order to lie ideally in the recess of the support element or, if desired and advantageous, even between the two support elements in order to be able to counteract a later load already with a certain moment ,

An advantageous embodiment of the invention provides an additional flat element, for example a board or a pane, as a stabilization aid for the flat support element on the stationary surface. This element can be mounted spatially in front of or behind the flat support element. If this additional stabilizing element is installed between the two flat support elements, another particularly stabilizing embodiment of the invention can provide grooves in this board in which the holders sit after the insertion process. A load on the holder would then cause a pressing action on these grooves, whereby an additional positive engagement would be given. This function could also be fulfilled by simple strips or point stop points. A second grid-shaped, flat support element, which was designed at least partially identical to the first flat grid-shaped support element, also fulfills this function.

If the two flat support elements are connected directly to one another, a further advantage arises, in particular with regard to the prior art. The holder, which is inserted through the first support member and the recess, at the same time abuts directly on the rear support member. This allows for correct production of the recess an absolute elimination of rotation of the holder by loading. Thus, the structure no longer carries only by magnetic adhesion to the rear support member, but in particular by positive locking, since a rotation of the holder is prevented. Although the retainer is integrated into the base with only a small portion of its depth, the load on the cantilevered retainer is scarcely limited, since it instantly becomes restrained.

A very similar effect arises when the recesses are excluded at an acute angle to the horizontal. As a result, the carriers meet at the same angle to the rear Supporting member. Of course, the holder at the ends then compensate for the angle of the misalignment again, so that a flat contact with the vertical support member can come to conditions. The holder therefore has an inclined position and will want to perform a twist under load. However, this rotation is instantaneously eliminated by the surface contact with the rear support member, whereby again a high load capacity can be realized. Preferably, the holder is skewed so that its higher part lies outside the base and its lower part lies inside the base. Another possibility of this modification is the misalignment of the entire support system or the support base. The holders can then remain arranged horizontally, as long as the angle of the misalignment is compensated at their end faces to ensure a flat contact.

The connection of the holder to the base is effected by a non-positive connection by means of a magnetic connection by means of magnetic attraction between the base and attached to the rear of the holder magnet and a positive connection of the holder in the grid-like support member. By this embodiment of the invention, in which the holders are connected both form-fitting manner with the grid-like holding element and non-positively with the base, is determined by the tool-free installation of the holder at the same time a defined angular position of the holder. Characterized the fixation of the support member is substantially improved by both, if undesirable, an irregular distance between the holders can be prevented, as well as a guarantee for always the same and exact alignment and inclination of the support elements can be placed on the holders.

The individual components can be made of any commercially available materials. Preferably, the base comprises metal as a substantial stock of material, which makes it magnetically or magnetizable can be formed. The base may for example consist of a rectangular plate, which can be conveniently extended modular.

Another embodiment of the invention is provided in that light sources or light bands can be integrated behind the base of the invention, ie between base and stationary surface on which the base is mounted, so as to provide preferably indirect illumination of the base and the grid-like holder device, in particular the base facing the back of the holder element to create. Preferably, a distance between the base and the stationary surface on which it is mounted is provided so as to allow an indirect light emission.

Of course, the holding device of the grid-like holding element is not limited to a uniform design of the holder. Rather, a variety of holders with different material properties, sizes and shapes can be arbitrarily combined and replaced. Furthermore, the holders can be mounted at any position in the grid holding member on the base. In this way, different functional, but also optical and usage-oriented requirements of the consumer can be optimally fulfilled. Furthermore, the holders can be used as a mark or for identification. In this case, individual holders can for example be equipped with labeling surfaces or labels.

The invention allows for different embodiments. To further clarify its basic principle, selected versions thereof are illustrated in the drawings and described below. Other features and advantages of the invention will become apparent from the following description of preferred embodiments with reference to the drawings.

The holding device according to the invention 1 is based on various perspective representations in the 1 to 6 explained in more detail below. Show it:

1 a three-dimensional view of a first embodiment of the holding system according to the invention, wherein a flat support member is connected by means of spacers with a grid-shaped support member and this grid-shaped support member holder, partially provided with borders, are positively inserted to subsequently receive frictional contact with the first flat support member;

2 a different three-dimensional view of the embodiment 1 ;

3 a different three-dimensional view of the embodiment 1 wherein the flat support member from the opposite side of in 1 shown perspective, whereby the mounted in the holders point magnets are visible because the support member has been slightly transparent;

4 a three-dimensional view of a second embodiment of the holding system according to the invention, wherein the flat support member and the grid-shaped support member have direct contact and it in the flat grid-shaped Support element only a recess, in which a hollow, forward open cube stuck as a holder;

5 a different three-dimensional view of the embodiment 4 wherein the flat support member from the opposite side of in 4 shown perspective, whereby the mounted in the holder surface magnets are visible because the support member has been slightly transparent displayed;

6 a three-dimensional view of a third embodiment, wherein the flat support member has an attachment shell, which on the one hand provides stability to the support element and can also serve as an additional positive fit for the holder by the attachment shell has grooves.

1 shows three-dimensionally an embodiment of the arrangement of a flat base 1 and a spatially in front of grid-shaped flat support element 2 , The distance between these two support elements 1 and 2 is by means of spacers 6 realized which the two support elements 1 and 2 connect with each other. In the support element 2 , are in a variably configurable grid recesses 3 integrated, whose internal surfaces as holding devices 8th for releasably fixable holders 4 serve. These holders 4 can thereby projecting on the support elements 1 and 2 be fixed. The difference of the internal dimension of the recesses 3 and the outer dimensions of the holders 4 determines the plug-in comfort and stability of the releasably fixable holder 4 , Once the holder 4 in recesses 3 be plugged, form-fitting connections and hold functions arise. The holders 4 can for additional stabilization of the complete installation borders 5 which, after the insertion process of the holder 4 in the recesses 3 the grid-shaped flat support element 2 put plan on this. To the process of inserting the holder 4 in the recesses 3 To facilitate, the holders can 4 have chamfered edges at the tips. The support element 1 is preferably made of a magnetizable or ferromagnetic material, which is the holder 4 non-positively attracts, since these at their tips, not shown in this figure, preferably permanent magnets 7 integrated or have applied. Once the permanent magnets 7 a certain distance to the support element 1 fall below the attraction between these elements and the holder 4 be frictionally on the support element 1 held, whereby the positive-locking function already described is guaranteed. The holders 4 can preferably be made as hooks to perform a good carrying function.

2 shows the in 1 described arrangement of the individual elements from a lateral perspective. You can see how the spacers 6 the flat grid-shaped support element 2 with the flat support element 1 connect and so create a defined distance between these two elements. The holders 4 are already through the grid-shaped support element 2 plugged and have full contact with the support element 1 , which is preferably made of magnetizable or ferromagnetic material, so that an attraction between just this element and, not shown here, preferably used permanent magnet 7 in the holders 4 comes about. To stabilize the entire installation, the holders 4 border 5 which, in the inserted state flat on the grid-shaped support element 2 issue. To increase the plug-in comfort, the holders can 4 at the tips of beveled edges, whereby the outer dimensions of the tips of the holder 4 decisive in relation to the internal dimensions of the recesses 3 and thus also to the distances of the holding devices 8th be minimized. When loading the holder 4 would be a distortion of this the episode. This rotation is due to the non-positive connection of the holder 4 with the support element 1 and in particular by the accuracy of fit of the holder 4 in the recesses 3 of the support element 2 prevented by the outer surfaces of the holder 4 to the fixtures 8th be pressed. Therefore, the scope of the holder 4 inside the recesses 3 crucial for the degree of stability.

3 shows a rear view of the in 1 and 2 described arrangement of the individual elements. The flat support element 1 is slightly transparent so you can see the rest of the installation. You can see the spacers 6 which the two support elements 1 and 2 connect together and grant a defined distance. The holders 4 are already through the recesses 3 and thus also between the holding devices 8th plugged and have full contact to the transparent support element shown 1 , The holders 4 may have chamfered edges at their tips to facilitate the mating process. At the top of the holder 4 are preferably permanent magnets 7 integrated or applied, which is an attractive force to the, preferably made of magnetizable or ferromagnetic material made supporting element 1 produce. The permanent magnets 7 are shown in a circle in this figure. As long as a sufficient load capacity can be guaranteed, the shape, size and arrangement of these permanent magnets 7 variable.

4 shows a, differing from the previous figures, execution of the installation described. The flat support element 1 is directly with the flat grid-shaped support element 2 connected. The recess 3 is in the support element 2 integrated and made large in relation to its dimensions. The holder 4 is in this representation, a hollow rectangular box, which has at most minimally smaller external dimensions, as the internal dimensions of the recess 3 , thus introducing the holder 4 in the recess 3 can be guaranteed. At the back of the holder 4 are, not shown in this figure, preferably permanent magnets 7 integrated or applied, which is an attractive force to the support element 1 , which is preferably made of magnetizable or ferromagnetic material produce. The accuracy of fit of the holder 4 in the recess 3 causes the stability of the installation, since a rotation of the holder 4 is excluded under load, as this with its outer surfaces against, not visible here, holding devices 8th on the insides of the recess 3 is pressed. The edges of the holder 4 which is on the support element 1 can preferably be chamfered to facilitate the plug-in comfort. This allows for less clearance between the holder 4 and the recess 3 be realized, whereby a high stability of the installation is to be expected.

5 shows the execution of in 4 described installation from the rear view. It can be seen that the holder 4 is designed as a hollow rectangular box and in the recess 3 which is in the support element 2 is inserted. The contact of the owner 4 to the support element 1 is achieved via a traction. The traction exists between the, preferably made of magnetizable or ferromagnetic material, support member 1 and preferably permanent magnets 7 , The permanent magnets 7 are preferably in the holder 4 integrated or applied to the final surfaces. This figure shows the permanent magnets 7 linear or planar. As long as a sufficient frictional connection can be ensured, the shape, size and arrangement of these permanent magnets 7 variable.

6 shows an advantageous development of in 1 illustrated and described installation of the individual elements to the effect, in front of the flat support member 1 another attachment shell 9 is applied, which grooves in a certain arrangement 10 having. These grooves 10 are to be arranged so that, in the flat grid-shaped support element 2 plugged, holder 4 with their tips reach into these grooves. The depth of the grooves is arbitrary and may even have the same dimension as the facing shell itself. This embodiment is particularly advantageous if the attachment shell 9 at least partially, namely at least in areas of the grooves, made of magnetizable or ferromagnetic material, as long as the groove depth is less than the thickness of the facing shell itself. Should the material not be magnetizable, it is recommended that the dimensions be designed so that the, behind the furring 9 lying, support element 1 , which in turn is preferably made of magnetizable or ferromagnetic material, at most such a large distance from the tips of the holder 4 that the attraction of the support element 1 and preferably permanent magnet 7 attached to the tips of the holder 4 sitting, but not shown here, continue to allow sufficient adhesion. Regardless, borders can 5 ensure additional stability of the complete installation. Also in this embodiment, it may be advantageous to the edges of the tips of the carrier 4 to be chamfered to increase the plug-in comfort. The bevels are allowed to measure the dimensions of the grooves 10 do not exceed, so that a clamping effect is generated as soon as the holder 4 be charged. This creates a double positive locking, with simultaneous adhesion.

The invention serves the cantilevered and releasable fixation of retaining elements on flat support elements. The fixation uses the principle of form and force closure.

The positive connection is by the intrusion of a holder 4 in a recess 3 a flat grid-shaped support element 2 reached. The adhesion is preferably due to a permanent magnet 7 and another flat support element 1 concluded by the permanent magnet 7 preferably at the end of the holder 4 attached or in this holder 4 is integrated and from the support element 1 is attracted. The traction takes over a position-securing function by direct contact between the holder 4 and the support element 1 guaranteed. By securing the position of the holder 4 on the support element 1 and thus also on the support element 2 which has spacers 6 a predefined distance to the support element 1 has, is also the positive connection of the holder 4 in the recess 3 of the support element 2 guaranteed. spacer 6 connect the support elements 1 and 2 with each other, creating a stable unit. For additional stabilization, it may be advantageous if the holder 4 a border 5 having. This border sits at the position where the holder 4 the flat grid-shaped support element 2 touched from the outside. Due to the frictional connection becomes the border 5 easy on the support element 2 pulled, creating a minimum voltage is built. When loading the holder 4 acts on the one hand, the adhesion between the permanent magnet 4 and the support element 1 and in particular the positive connection between the holder 4 and the recess 3 , This is a twist of the holder 4 through the, in the recess inside directed, holding devices 8th prevented. A further execution of the installation sees an additional attachment shell in front of the support element 1 in front, which is equipped with grooves to the holder 4 to protect with a second positive fit of the described rotation.

The flat support element 1 is preferably made of a magnetizable or ferromagnetic material and is not subject to form constraints. Therefore, it can take any dimensions in all three dimensions and be formed both angular and round or curved. It is also conceivable that a magnetizable or ferromagnetic material is incorporated in a non-magnetizable material such as wood. The coverage of the magnetizable material may then be selected to be so large that a sufficient attraction force to the permanent magnet 7 can still be ensured. The flat grid-shaped support element 2 is preferably made of a stable material such as wood or metal, wherein the property of non-magnetization can form a decisive advantage, but at the same time is not a mandatory requirement. This support element 2 is also not subject to any formal restrictions and can take on any dimensions in all three dimensions and be formed both angular and round or curved. In this support element 2 are recesses in a regular or irregular grid 3 integrated, which by means of their inner surfaces holding devices 8th represent. The shape and design of the recesses and thus the holding device is open form and arbitrary. Overall, it offers a grid-like arrangement of these elements in order to provide a visually uniform image and the greatest possible variation in mounting the holder 4 to ensure. The holders 4 are subject to the shape specification of the recesses 3 because of these by their holding devices 8th the basis of the positive connection between these same surfaces and the outer surfaces of the carrier 4 represent. It should be noted that the ratio of the outer dimensions of the carrier 4 and the clear dimension of the recess 3 directly about stability and comfort. Therefore, it is particularly advantageous the holder 4 to provide at the top with chamfered edges to allow easier insertion. The shape of the holder 4 follows as mentioned the shape of the recess 3 and can therefore be square, round or bent. Irrelevant, however, is whether the holder 4 made of solid material or hollow inside. For smaller dimensions, the variant offers solid material, whereas for larger dimensions, the hollow design would make sense, since the free space can be used as a storage area. The material of the holder 4 is arbitrary. There is therefore the possibility to carry out the holder, for example, as a permanent magnet, whereby the attachment or integration of a permanent magnet 7 could be waived. However, the much more comfortable and economical design provides exactly this preferably attachment or integration of a permanent magnet 7 This magnet can assume any size and shape. Therefore, he can take ball, disc, cylinder, cube, cone or other volume shape. The strength of the permanent magnet 7 decides on the one hand about its shear stability and about the catchment area of its attraction. The stronger the permanent magnet 7 is chosen, the greater its catchment area and the sooner becomes the holder 4 from the support element 1 attracted and positioned. In order to increase the shearing force, it would be advantageous the contact surface between the permanent magnet 7 and support element 1 equipped with a non-slip material. The material of the permanent magnet 7 is freely selectable and is based on the guidelines for adhesion and the available space. As already mentioned form the inner surfaces of the recess 3 holders 8th that the form fit to the holders 4 represent. It is advantageous if these holding devices have a flat surface to a maximum contact with the holder 4 to be able to produce. It could also be advantageous if these surfaces were provided with a non-slip material. This non-slip material would also have a positive effect on the faces of the holder 4 pointing to the flat support element 1 to meet. The distance between the supporting elements 1 and 2 is about spacers 6 guaranteed. These spacers 6 also connect the support elements 1 and 2 among themselves. On spacers 6 can be omitted if the support element 2 directly on the support element 1 is attached. The fixation of the support elements 1 and 2 with each other, directly or via spacers 6 , can be done by means of screws, glue, friction or other liability. The embodiment via friction allows a detachable attachment of the support element 2 on the support element 1 , whereby a higher flexibility is achieved. When connecting the support elements by means of spacers, provides an advantageous embodiment of the installation, that between the support element 2 and the support element 1 an attachment shell 9 is attached, which directly on the support element 1 is fixed. This attachment shell 9 is preferably made either of magnetizable or ferromagnetic material to continue the holder 4 to be able to attract and allow the adhesion. Will the attachment shell 9 made of a non-magnetizable material, it makes sense to dimension the dimensions in magnetic force axis of action so that continue to allow sufficient attraction. This attachment shell is particularly advantageous 9 then, if they are the same Grid in which the recesses are applied, has grooves. These grooves minimize on the one hand the material thickness of a possibly non-magnetizable material and at the same time cause a second positive locking by the holder 4 drive into these grooves while experiencing the adhesion. As a result, the threat of rotation of the holder is an additional times positively prevented. In order to increase the flexibility of the entire installation, it is not just about individual holders 4 to use but multiple holders 4 to string together to add the carrying capacity. The attachment of the holder on the rear surface of a board could allow a flat use of the cantilevered components. Another conceivable possibility would be the support of a board on at least two holders, which would also be an area available as a support. A particularly advantageous embodiment would be the attachment of further permanent magnets and magnetizable materials to the holders 4 and the board described, whereby these elements could be firmly connected to each other. By a small local displacement of the permanent magnets and the magnetizable materials, one could again a small voltage against the support element 2 which could further strengthen overall stability.

The arrangement of the permanent magnets on the holders and the design of the support element of magnetizable or ferromagnetic material is economical, which is why a double application of permanent magnets is not excluded. This applies both when attaching the holder 4 on the support element 1 , as well as in the fixation of the mentioned boards on the holders 4 , In addition, according to the principle of kinematic reversal, all the components of the fixation can be exchanged.

LIST OF REFERENCE NUMBERS

1

Flat support element

2

Flat grid-shaped support element

3

recess

4

holder

5

border

6

spacer

7

permanent magnet

8th

holder

9

furring

10

groove

Cited patent literature

• - DE 200 11 351 U1
• - DE 10 2010 017 771 A1
• - DE 203 03 813 U1
• - DE 20 2008 002 066 U1
• - DE 199 09 440 C1
• - DE 81 23 758 U1

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 20011351 U1 [0005]
• DE 102010017771 A1 [0008]
• DE 20303813 U1 [0009]
• DE 202008002066 U1 [0010]
• DE 19909440 C1 [0011]
• DE 8123758 [0012]

Claims (16)

A fixable on a particular fixed surface holding system of flat support elements ( 1 and 2 ), the arrangement comprising a first grid-shaped carrier element ( 2 ), the recesses ( 3 ), which holding devices ( 8th ) for holders ( 4 ) and a second support element ( 1 ) bears against the stationary surface, characterized in that in the holding devices ( 8th ) Holder ( 4 ) are releasably positively fixed according to the grid dimension and on each holder ( 4 ) at least one permanent magnet ( 7 ) provided with the second support element ( 1 ) forms a magnetic, releasable adhesion. Holding system according to claim 1, characterized in that the two flat support elements ( 1 and 2 ) are connected by spacers. Holding system according to claim 1, characterized in that the two flat support elements ( 1 and 2 ) have direct contact with each other. Holding system according to at least one of the preceding claims, characterized in that the second support element ( 1 ) is a flat metallic plate, which has a magnetic adhesion to the permanent magnet ( 7 ) in the holder ( 4 ). Holding system according to at least one of the preceding claims, characterized in that the holders ( 4 ) consist of solid material, the nature of the material does not matter. Holding system according to at least one of the preceding claims, characterized in that the holders ( 4 ) are hollow and at least open to the front, the nature of their material playing no role, whereby the cavity of the holder ( 4 ) can be used as storage space. Holding system according to at least one of the preceding claims, characterized in that the magnetic attraction between holder ( 4 ) and the magnetic or ferromagnetic support element ( 1 ) by at least one in the holder ( 4 ) one or attached punctiform permanent magnets ( 7 ) comes about. Holding system according to at least one of the preceding claims, characterized in that the magnetic attraction between holder ( 4 ) and the magnetic or ferromagnetic support element ( 1 ) by at least one in the holder ( 4 ) one or attached planar permanent magnet ( 7 ) comes about. Holding system according to at least one of the preceding claims, characterized in that the holders ( 4 ) at least one border ( 5 ) which form-fit on the respective recess ( 3 ) of the grid-shaped support element ( 2 ) rests flat and in this way additional stability of the holder ( 4 ) and the entire holding system guaranteed. Holding system according to at least one of the preceding claims, characterized in that the holders ( 4 ) additional permanent magnets ( 7 ) on its upper edge in order to 4 ) to be able to fix an additional board by means of magnetic attraction by the board has magnetic or ferromagnetic components and can be used for example as a shelf. Holding system according to at least one of the preceding claims, characterized in that at least two holders ( 4 ) are mounted on the front side of a board or arise from this or are connected to one another such that a stable unit is formed in order to attach this unit within a process to the holding system and the unit can be used, for example, as a shelf. Holding system according to at least one of the preceding claims, characterized in that the flat support elements ( 1 ) is applied from magnetic or ferromagnetic material for additional stability on an auxiliary plate made of any material. Holding system according to at least one of the preceding claims, characterized in that the flat support elements ( 1 ) is applied from magnetic or ferromagnetic material for additional stability on an auxiliary plate made of any material and this material is locally between the two support elements ( 1 and 2 ) and thus as an intent shell ( 9 ) of the support element ( 1 ) and grooves ( 10 ) into which the holders ( 4 ) are pulled magnetically. Holding system according to at least one of the preceding claims, characterized in that on the flat support element ( 1 ) horizontal strips are attached, which the holder ( 4 ) additional positive locking, in the, expected, direction of rotation of the holder ( 4 ) under load. Holding system according to at least one of the preceding claims, characterized in that the grid-shaped supporting element ( 2 ) has only one recess into which only a holder ( 4 ) is introduced. Holding system according to at least one of the preceding claims, characterized in that the recesses or the rest of the support system are mounted at an angle to the horizontal, so that the rear end faces of the holder have an angle to the rod axes to produce under pressure a pressure to the rear support member.

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