EP3120736A1 - Magnetic presentation and storage system for shoes and shoetree for same - Google Patents

Abstract

Previously known magnetic force-supported presentation and storage systems (1) for shoes (7) comprise a base element (2) with an at least partially magnetizable or magnetic, metallic surface and a magnetic element (5, 35), which in electromagnetic interaction with the metallic surface for fixing of the shoe (7) contributes to the base element (2). To allow starting from this, an aesthetically pleasing mounting of shoes (7) of different shoe sizes in a small space even without individual adjustment of the holder, it is proposed that the magnetic element (5, 35) be designed so that it simultaneously for placement within the foot-receiving space of the shoe to be held (7) and for fixing the shoe (7) is suitable.

Description

Technical area

The present invention relates to a magnetic force-supported presentation and storage system for a shoe with shoe bottom, toe, heel and a foot receiving space, comprising a base member having at least partially a magnetizable or magnetic, metallic surface, and a magnetic element in electromagnetic interaction with the metallic surface contributes to the fixation of the shoe to the base element.

Moreover, the invention relates to a shoe tree for use in a presentation and storage system for a shoe, wherein the shoe tree comprises a front molding insertable into a shoe front.

Moreover, the invention relates to a method for fixing a shoe with shoe bottom, toe, shoe heel and a foot-receiving space on a base member having at least partially a magnetizable or magnetic metallic surface, using a magnetic element which in electromagnetic interaction with the metallic Surface contributes to the fixation of the shoe to the base member.

State of the art

In the commercial sector, such devices are typically used for the appealing presentation of footwear in shop windows, shops and exhibition stands.

For example, the DE 92 05 043 U1 for the presentation of shoes on decorative surfaces of shop windows before a system having a magnetic wall on which a support member for the shoe can be arbitrarily placed. For fixing to the magnetic wall, the carrier element is equipped with a magnet.

Another Ladeneinrichtungssystem with a stand made of a magnetizable material, on which support elements can be placed and fixed by means of magnets, is from the DE 10 2007 053 635 A1 known. The support elements serve to hold the object to be presented, such as footwear.

In the private home shoes are often stowed in more or less bulky shelves or cabinets. To reduce the space required, teaches AT 12 823 U1 a magnetic shoe storage system in which the shoe is attached to a modified spiral spring tensioner. Spiral spring tensioners usually consist of a shaped piece which can be inserted into a shoe front part and a tensioning element in the form of a metallic spiral spring. The AT 12 823 U1 suggests to remove the metallic coil spring and replace it with a screwed-on magnetic plate. The metal plate is then fixed to a metal wall and attached the shoe to be held on the remaining shoe tensioner fitting. However, the shoe attached to the shoe tensioner fitting has - not very well - with its sole to the outside.

An improvement in this regard will be made at the time of JP H1037630 A reached known shoe-holding system. For holding a two-part wire hanger molding is used, in which the one free wire ends form a bracket portion for engagement in a shoe front part and the other free wire ends are inserted horizontally angled into holes in a magnetic element. The magnetic element is fixed to a metal door. The horizontally angled extending portion of the wire ends has a length which is greater than the height of the heel of the shoe to be held. As a result, it is possible that the heel of the shoe-with the shoe sole resting against the magnet element-can be overlapped externally by the wire hanger molding and, as a result, the shoe front part can be pulled over the hanger region.

Ironing region and horizontally angled extending portion of the wire hanger molding are each adapted to the dimensions of the shoe pair to be held. The serving as a carrier magnetic element is visible.

A similar appearance arises also with the domestic storage system, as it is from the JP 2011-000213 A is known. The shoes are also held on a support so that they with their sole (the Shoe bottom) against a metallic wall, such as against a door or the cladding of a desk. The carrier is designed as a circumferential rectangular frame, one longitudinal side of which is provided for releasable connection to the metallic wall with a magnet. The rectangular frame is to be oriented on the wall so that there is a vertically continuous opening through which a shoe pair can be inserted from above and with the shoe tips pointing down.

The serving as a carrier circumferential rectangular frame is visible. Its opening width is adapted to the dimensions of the respective pair of shoes to be held so that it can not slip through the passage opening. The bracket different sized shoes therefore requires a certain individualization of the wearer, which is accompanied either with manufacturing effort for subsequent adaptation or complex storage requirements asked carrier sizes.

Technical task

The previously known magnetic force-supported shoe presentation and storage systems are equipped with shoe straps that either require an individual adaptation to the sizes of the shoes to be held, are visible to an observer or force a disadvantageous orientation of the shoes to be held.

The invention has for its object to provide a shoe presentation and storage system that allows an aesthetically pleasing mounting shoes of different shoe sizes in a small space, even without individual adjustment.

It is another object of the present invention to provide a shoe tightener which is advantageously designed for use in such a magnetic force-based shoe presentation and storage system.

In addition, a method should be specified, which allows an aesthetically pleasing mounting shoes of different shoe sizes in a small space, even without individual adjustment.

General description of the invention

With regard to the shoe presentation and storage system, this object is achieved on the basis of a system of the type mentioned in the present invention that the magnetic element is designed for placement within the foot-receiving space and for fixing the shoe to the base member.

The magnetic force-supported support of the shoe is based on electromagnetic interaction between the magnetic element and the metallic surface of the base element. To form the electromagnetic interaction, it is sufficient if either the magnetic element or the metallic surface acts as a permanent or as an electromagnet; the other element can only be magnetizable, so for example, consist of a ferromagnetic but not necessarily magnetic material.

In contrast to the known magnetic-force-supported shoe holders at least one magnetic element is provided in the invention and designed so that it is arranged during use as intended within the foot-receiving space. The field lines of the magnetic field contributing to the shoe holder thus extend from the magnetic element to the base element through a shoe wall; for example, through the shoe bottom, when the shoe sole rests against the base element. The designed for this magnetic element on the one hand has a small size, which allows an arrangement in the foot-receiving space. On the other hand, it is designed to fix the shoe to the base member so that in combination with the base member it has a magnetic energy density sufficient to fix the shoe through the shoe wall. The magnetic energy density is the magnetic energy related to the volume of the magnetic element. A measure of the magnetic energy adapted for the present application is the tensile force required to disengage the magnetic element and the base element. It scales to a first approximation with the volume of the magnetic element. The larger the volume, the higher the tensile force (at the same magnetic energy density). The magnetic field strength (the magnetic field lines) and thus the tensile force are weakened by the shoe wall - depending on the type and thickness.

The magnetic element volume can not be arbitrarily large, but it is limited by the available foot-receiving space. In view of this volume limitation and the mentioned weakening of the field strength, the magnetic energy density of commercial permanent magnets made of steel, hard magnetic ferrites or aluminum-nickel-cobalt alloys is usually too low to ensure a secure shoe holder. Magnetic materials with high magnetic energy density are, for example, rare earth magnet alloys with the typical alloy constituents iron, cobalt, nickel and rare earth metal (neodymium, samarium, praseodymium, dysprosium, terbium, gadolinium, yttrium), in particular compositions of neodymium-iron-boron and samarium Cobalt-iron, as well as alloys of bismuth, manganese and iron (known as "Bismano").

The arrangement of the magnetic element in the foot-receiving space makes it possible to dispense with a separate magnet-supported support for holding the shoe. If the magnetic element disappears completely in the foot-receiving space, the holder is not visible to a viewer and for him the shoe seems to stick to the base element.

The base element consists of one part or several parts. The metallic surface is an integral part of the base element or it forms a layer on a base body. In the former case, the base member is made of a magnetic or magnetizable metal, in the latter case, the base member of the base body and metallic, magnetic or magnetizable layer, which may be closed or interrupted, is formed. The metallic surface simultaneously forms a surface of the base member or is covered by a film, such as a lacquer coating.

The base element not only provides the metallic surface for fixing, but also a receptacle or footprint for the shoe to be held or for several shoes to be held ready. It significantly determines the position and orientation of the held shoe. Geometry and designated spatial arrangement of the base member are coordinated with respect to a small footprint so that the provided by the base member footprint for the shoe extends vertically or at an acute angle (<45 °) inclined to the vertical plane. The angle range between 0 and 45 degrees for the orientation of the Standing surface with respect to the vertical plane is hereinafter referred to as "vertical orientation" for the sake of simplicity.

With regard to the suitability of the base element for use in the presentation and storage system according to the invention, it has: in combination with the magnetic element, a magnetic energy density which is sufficient to fix the shoe through the shoe wall. Suitable permanent magnetic alloys are explained above in connection with the magnetic element.

It has proven particularly useful when the magnetic element is designed for placement on the shoe bottom in the area of the shoe tip.

To hold the shoe, a magnetic element that rests directly or indirectly via an intermediate element - on the shoe floor is sufficient. The field lines of the electromagnetic interaction thus run through the shoe bottom in the area of the toe. There, the shoe bottom is usually thin compared to the shoe heel, so that the magnetic field strength is weakened by the shoe bottom comparatively little. The selective fixation by means of magnetic element on the toe tip allows a rotational movement about the fixation point. Since the center of mass of a shoe is always closer to the heel than to the toe, the sole rotatable fixation on the toe in "vertical orientation" of the shoe causes gravity to cause the toe to point up and the heel to descend.

The required high tensile force between the base member and magnetic element can cause the removal of the magnetic element from the base element is difficult and may even be accomplished only with a tool. This is especially true when the magnetic element and the base element come into direct contact with each other, ie without the interposition of a shoe bottom or other base, as may happen during the storage of the magnetic element on the metal surface of the base member for later use.

In view of this, the magnetic element is preferably connected to a handling element.

The handling element facilitates the insertion of the magnetic element into the foot-receiving space and in particular the removal of the magnetic element from Base element. It is designed for example as a handle, which partially surrounds the actual magnetic body.

In a particularly preferred embodiment of the presentation and storage system according to the invention, it is provided that the handling element is designed as a shoe tree.

The magnetic element is a solid or detachable part of a shoe trees for use in the shoe to be held. The shoe tree comprises a shaped piece, also referred to as a front sheet, which is inserted into the shoe front part. By inserting the shaped piece into the shoe, the magnetic element fixed thereto or it can be reproducibly moved to one and the same position within the foot receiving space at the same time.

Preferably, the magnetic element is designed for receiving in a recess of the shoe trees. Schuhspanner recording and magnetic element are either solvable and optionally form a form-fitting or frictionally engaged with each other joint connection, or the magnetic element is an integral part of the shoe trees and, for example, firmly glued into the receptacle. The receptacle is preferably located in an area of the shoe tensioner, which rests against the drawer when used as intended.

For storage for the intended use of the magnetic element or it can be kept visible on the base element several magnetic elements. Even when used for shoe holder itself, the magnetic element can be at least partially visible to a viewer. For an aesthetically appealing holding system, the magnetic element is preferably designed as a decorative element. For this purpose, the outwardly facing surface of the magnetic element is formed for example by a color-coordinated or structured cover. Alternatively or additionally, the magnetic element exhibits optical markings or markings which, for example, indicate or represent position, orientation or suitability for use or information about its magnetic strength or size.

In a preferred embodiment of the presentation and storage system, the base element is designed as a self-supporting hollow body.

In a separate attachment of the base element to the floor, wall or ceiling can be omitted. The base element is designed, for example, as a cube, hollow cylinder, pyramid or frame and can be positioned as required on the intended place or removed therefrom. The design as a hollow body results in a filigree compared to the solid solid body and a lower weight.

On the other hand, the self-supporting embodiment of the base element requires a certain volume and a corresponding space requirement.

This disadvantage avoids another suitable embodiment of the presentation and storage system, wherein the base member is formed as a plate.

The plate-shaped base element takes up little space. It consists of magnetic or magnetizable metal or it has a magnetic or magnetizable, metallic surface, which is executed on one side or on both sides. Apart from any edges or locking means, the plate is flat or curved. Optionally, it is designed with attachment or support means for hanging or standing storage or for attachment to a vertical wall or furniture surface. As a rule, there is a vertical or approximately vertical orientation of the plan sides and thus the metallic surface and, consequently, a "vertical orientation" for the shoe to be held.

Another embodiment of the presentation and storage system according to the invention is characterized in that the base element is designed as a foldable or rollable curtain.

The curtain comprises at least one metallic layer which is either magnetizable or magnetic, such as a magnetic foil, forming the metallic surface. The curtain can be relatively easily designed, suspended, clamped or spread in the available space, resulting in a vertical or approximately vertical orientation of the metallic surface. When folded or rolled up, it requires little storage space.

It has also proved to be advantageous if the base element is provided with a latching contour for supporting the shoe heel.

The locking contour contributes to the support of the shoe from below and to maintain a predetermined orientation. This is particularly helpful when the shoe is rotatable about a bearing point, such as in the case of fixing the shoe to the base member with only one magnetic element. The locking contour may comprise a plurality of punctiform or elongated locking elements which are distributed on the base member in a predetermined pattern. The locking contour is either fixed or it is adapted individually to the needs, the locking elements are displaceable in the latter case on the base member.

Preferably, the locking contour comprises a horizontally extending and placed on the base element paragraph support bar or incorporated into the base element edge.

The at least one strip or the at least one edge cause an optical division of an otherwise flat metallic surface of the base element, so that the locking elements in addition to the support function also has an aesthetic effect.

In the presentation and storage system according to the invention, the base element is preferably equipped with a connection to an electrical power supply.

The power supply serves, for example, to be able to operate the metallic surface of the base element as an electromagnet, to illuminate the presentation and storage system or to install an alarm system.

With regard to the shoe trees, the above object is achieved starting from a shoe trees of the type mentioned in the present invention that the front mold has a recess into which a magnetic element is inserted.

Usual shoe trees are composed of several parts. The front mold is pushed into the shoe front under slight pressure by means of a tension member connected to the front sheet. The tensioning element is designed for example as a spiral spring, in high-quality shoe tensioners as a telescopic spring or threaded element between the front blade and an optional rear fitting (heel piece).

Of the known shoe tensioners, the shoe tree according to the invention differs in that the front mold is positively, positively or materially connected to at least one magnetic element. The magnetic element comprises a magnet or a component made of a ferromagnetic material and, in interaction with a base element of a magnetic or magnetizable material, is suitable for fixing a shoe to the base element. For this purpose, the magnet is introduced together with the shoe trees in the foot-receiving space of the shoe to be held. By inserting the front fitting into the shoe, at the same time, the magnetic element fixed thereto or therein is reproducibly moved to one and the same position within the foot-receiving space.

The magnetic element has a size that allows placement in the foot-receiving space and, in combination with the base element, has a magnetic energy density sufficient to fix the shoe through the shoe wall on the base element.

For receiving the magnetic element of the shoe trees has a recess, which preferably has an opening in the direction of the shoe bottom of the shoe to be held. This direction is clearly defined by the construction of the shoe trees. The recess is preferably located in an area of the shoe trees, which rests on the shoe bottom when used as intended. Shoe tensioner recess and magnetic element are either detachable and optionally form a form-fitting or frictionally engaged joint connection, or the magnetic element is an integral part of the shoe trees and glued, for example, in the recess.

With regard to the method, the object stated above, starting from a method of the type mentioned in the introduction, is achieved according to the invention in that the magnetic element is arranged within the foot-receiving space.

In the method according to the invention, the magnetic element is arranged within the foot receiving space, so that the field lines of the magnetic field contributing to the shoe holder extend from the magnetic element to the base element through a shoe wall. This can be dispensed with a separate magnet-supported support for holding the shoe (as in the known holding methods). The shoe is thereby fixed on the base element, that its footprint on the base element extends vertically or at an acute angle (<45 °) inclined to the vertical plane.

The presentation and storage system according to the invention is for the

Use designed in this procedure. The specific and preferred embodiments of this system are also specific and preferred embodiments of the method and the explanations given above for this system also apply to the method according to the invention.

embodiment

Figur 1

eine erste Ausführungsform des erfindungsgemäßen Präsentations- und Aufbewahrungssystems mit vertikaler Ausrichtung des Basiselements in einer Seitenansicht,

Figur 2

die Ausführungsform des erfindungsgemäßen Präsentations- und Aufbewahrungssystems von Figur 1 aber mit einer zur Vertikalen geneigten Ausrichtung des Basiselements in einer Seitenansicht,

Figur 3

eine Ausführungsform des erfindungsgemäßen Präsentations- und Aufbewahrungssystems mit einem Magnetelement, das in einem Schuhspanner aufgenommen ist,

Figur 4

einen Schuhspanner mit integriertem Magneten gemäß der Erfindung in einer Draufsicht,

Figur 5

den Schuhspanner von Figur 4 in einem Schnitt entlang der Linie A-A,

Figur 6

einen Schuhspanner mit integrierten ferromagnetischen Metallelementen gemäß der Erfindung in einer Draufsicht eine und,

Figur 7

das erfindungsgemäße Präsentations- und Aufbewahrungssystems in Frontalansicht.

The invention will be explained in more detail with reference to embodiments and a drawing. In detail shows in a schematic representation:

FIG. 1

a first embodiment of the presentation and storage system according to the invention with vertical orientation of the base member in a side view,

FIG. 2

the embodiment of the presentation and storage system of FIG. 1 but with a vertical orientation of the base element in a side view,

FIG. 3

an embodiment of the presentation and storage system according to the invention with a magnetic element which is accommodated in a shoe tree,

FIG. 4

a shoe tensioner with integrated magnet according to the invention in a plan view,

FIG. 5

the shoe trees of FIG. 4 in a section along the line AA,

FIG. 6

a shoe tree with integrated ferromagnetic metal elements according to the invention in a plan view and

FIG. 7

the presentation and storage system according to the invention in a front view.

In the in the Figures 1 and 2 Shoe storage system 1 shown is a base member in the form of a 1.5 mm thick plate 2 of ferritic, magnetizable stainless steel provided. In the area of the lower plate edge 4, a support strip 3 of magnetic material is detachably mounted. The support strip 3 has rectangular cross section (2 mm x 3 mm) and it extends over the entire width of the plate 2 (as well as in FIG. 7 shown).

In addition, the shoe storage system 1 comprises a plurality of neodymium permanent magnets 5 (see also FIG FIG. 5 ), which are made of an alloy of iron, boron and neodymium and which are coated with a shiny nickel layer. The neodymium magnets 5 are present in different sizes and shapes, in particular in disk and cuboid form. One of the neodymium magnets 5 is arranged in the foot-receiving space 6 of a low shoe 7 with shoe size 45, which rests with his shoe sole 8 on the stainless steel plate 2 and rests with his heel 9 on the upper edge of the support bar 3.

Hereinafter, the functions of the individual components (2, 3, 5) of the shoe storage system 1 will be explained.

The stainless steel plate 2 provides a footprint 10 for a plurality of shoes to be held 7 in a small space and a metallic surface for their fixation ready. Depending on the orientation of the stainless steel plate 2 - it is for example attached to a vertical wall (as in FIG. 1 shown) or it is leaning against the wall standing on the ground (as in FIG. 2 shown) - the footprint 10 is oriented vertically or approximately vertically. In the latter case, the angle between the base 10 in relation to the vertical plane is a maximum of 45 degrees; like this one in FIG. 2 indicated angle α indicates.

The neodymium permanent magnet 5 is arranged resting on the shoe floor in the region of the toe. He is so small that he fits in the foot-receiving space 6 of the shoe to be held 7 and disappears completely in it. The required to hold the shoe 7 traction depends on the weight of the shoe 7 and on the thickness and nature of the shoe sole 8. In the embodiment, a shoe 7 with a weight of about 450 g and a leather sole 8 with a thickness of about 3 mm to keep. The magnet 5 is designed as a round disc with a diameter of 25 mm and a thickness of 7 mm, the nominal tensile force is about 12 kg. This tensile force is sufficient for selective fixation of the shoe 7 on the base 10th

The support strip 3 is used for alignment and supplementary support of the shoe paragraph. 9

The arrangement of the neodymium permanent magnet 5 in the foot-receiving space 6 makes it possible to dispense with a separate magnet-supported support for holding the shoe. The magnet 5 is not visible to a viewer and for him the shoe seems to stick to the stainless steel plate 2. Overall, this results in a visually-aesthetically pleasing way of shoe holder in a small space.

At the in FIG. 3 For footwear display and storage system 31 shown, the same reference numerals are used for the same or equivalent components and components of the system as in FIG FIG. 1 , A special feature of the system 31 is that in the shoe to be held 7 a shoe tree 30 is inserted for shoe size 45, which has a recess into which a neodymium permanent magnet 35 is glued.

In the shoe tree 30, a front sheet 34 is connected to a heel piece 33 via a metallic coil spring 32. In the usual way, the front blade 34 is pressed by means of the coil spring 32 under slight pressure in the shoe front part and the heel piece 33 against the inside of the shoe rear cap. The recess for receiving the permanent magnet 35 is provided on the underside of the front blade 34, so that it rests as close as possible to the shoe bottom. Since in conventional shoe tensioners the shoe bottom 41 (see FIG. 5 ) facing front sheet bottom 37 (see FIG. 5 ) has a groove or bulge up, there may be a gap between shoe bottom 51 and magnet 35.

The shoe tree 30 is based on the FIGS. 4 and 5 explained in more detail. He fulfills several functions. First, it stabilizes the shape of the shoe 7, as usual, and on the other he takes the magnet 35 and ensures reproducible its correct positioning within the foot-receiving space to ensure optimal adhesion to the stainless steel plate 2.

The total weight of shoe 7 and shoe trees 30 is 650 g. For holding this weight (with a sole thickness of 3 mm and a gap between magnet 35 and shoe bottom of 1 mm), the magnet 35 is designed as a round disc with a diameter of 30 mm and a thickness of 15 mm, the nominal tensile force is about 23 kg , This tensile force is sufficient for selective fixation of the shoe 7 by means of the shoe tensioner 30 on the base 10th FIG. 4 shows the shoe tree 30, in which the magnet 35 is integrated. Size, force and position of the magnet 35 are selected so that the shoe 7 optimally adheres to the stainless steel plate 2. The shoe trees 30 is composed of three parts, namely the made of beech wood front sheet 34, which is connected via a metallic coil spring 32 with the heel piece 33, which also consists of beech wood. The underside 37 of the front blade 34, resting on the shoe bottom 41 during use as intended for shoe tightening, is provided with a circular cross-section recess 36 with a diameter of 30.5 mm, which has an opening facing downwards (in the direction of the shoe bottom 41) the magnet 35 is glued.

The cross-sectional view of FIG. 5 schematically shows the support of the lower edge 38 of the front blade 34 on the shoe bottom 41 (in the neck and only indicated). The depth of the recess 36 and the height of the magnet 35 glued therein are matched to one another such that the smallest possible gap results between the magnet 35 and the shoe bottom 41; Ideally, bottom edge 38 and bottom 39 of magnet 35 are at the same height level so that there is no gap at all. When in the FIG. 5 In the embodiment shown, the depth of the recess 26 is also selected such that the neodymium permanent magnet 35 is received therein at half its height.

In an alternative embodiment of the shoe tightener according to the invention, a magnetic element made of a non-magnetic, but ferromagnetic material is used in the shoe trees instead of the magnet 35, in which case instead of the magnetizable stainless steel plate 2, a base member made of a magnetic material for receiving and holding the shoe is to achieve the required for shoe holder electromagnetic interaction with the magnetic element.

FIG. 6 shows a suitable embodiment of the inventive shoe tree 60 in a view on the underside (facing the shoe bottom), In contrast to the in FIG. 4 shown embodiment, this is provided with two recesses 66, 68, in each of which a ferromagnetic metal part 65, 67 is glued. One of the recesses (66) has a round cross-section and is corresponding to the receptacle 36 of the embodiment of FIG. 4 executed. This (66) serves to receive a cylindrical metal part 65 with a round cross section with an outer diameter of 30 mm and a thickness of 15 mm. The other recess 68 is made at the top of the shoe tensioner 60 in a U-shape. It serves to receive a U-shaped metal part 67 with a width of 10 mm and a thickness of 10 mm. The depths of the two recesses 66 and 68 and the thicknesses of the metal parts glued therein 65; 67 are coordinated so that the outwardly facing, free end faces of the metal parts 65, 67 extend approximately in the same height level as the lower edge 38 of the front blade 34.

The shoe tensioner 60 is designed for use with a base element which consists entirely or partially of magnetic material, so that the ferromagnetic metal parts 65: 67 of the shoe tensioner 60 according to the invention are fixed and held on the magnetic base element by electromagnetic interaction.

FIG. 7 shows an exemplary frontal view of the presentation and storage system 1 for magnetically supported support of a plurality of shoes 7. The base element is made entirely of ferromagnetic stainless steel or it has at defined locations on magnetic or ferromagnetic surface areas that interact with the magnets in the respective foot Reception areas of the shoe are used and hold the shoe in the desired position. Shape, size and material of the base member, the locking elements and the magnets are on the one hand to the desired number of shoes to be held and on the other hand adaptable to design requirements. A number of magnets 42 of different thicknesses and shapes, colors and sizes are provided on the stainless steel plate 2 in stock for use. The magnets 42 are so strong that they can not be easily removed from it in direct contact with the stainless steel plate 2. They are therefore provided with a protruding upper edge, which can be attacked to remove the magnet of a handle or other handle. In addition, disc-shaped documents (not shown) made of leather or felt are provided, which facilitate the removal in addition.

Claims (15)

Magnetic-based presentation and storage system (1) for a shoe (7) with shoe bottom (41), toe, shoe heel (9) and a foot-receiving space (6), comprising a base element (2) which at least partially a magnetizable or magnetic, metallic surface, and a magnetic element (5; 35), which in electromagnetic interaction with the metallic surface for fixing the shoe (7) contributes to the base element (2), characterized in that the magnetic element (5; 35) for arrangement within the foot-receiving space (6) and for fixing the shoe (7) on the base element (2) is designed. Presentation and storage system according to claim 1, characterized in that the magnetic element (5; 35) is designed for placement on the shoe bottom (41) in the region of the toe. Presentation and storage system according to claim 1 or 2, characterized in that the magnetic element (5; 35) or the base element (2) contains a magnet of a rare earth magnet alloy or of a bismuth manganese iron alloy. Presentation and storage system according to one of the preceding claims, characterized in that the magnetic element (5; 35) is connected to a handling element. Presentation and storage system according to claim 4, characterized in that the handling element is designed as a shoe tree (30). Presentation and storage system according to claim 5, characterized in that the magnetic element (35) is received in a recess (36) of the shoe tensioner (30). Presentation and storage system according to one of the preceding claims, characterized in that the magnetic element (5; 35) is designed as a decorative element. Presentation and storage system according to one of the preceding claims, characterized in that the base element is designed as a self-supporting hollow body. Presentation and storage system according to one of claims 1 to 7, characterized in that the base element (2) is formed as a plate. Presentation and storage system according to one of the preceding claims, characterized in that the base element (2) is provided with a latching contour (3) for supporting the shoe heel (9). Presentation and storage system according to claim 10, characterized in that the latching contour (3) comprises a horizontally extending and on the base element (2) patch paragraph support bar or incorporated into the base element edge. Presentation and storage system according to one of the preceding claims, characterized in that the base element is equipped with a connection to an electrical power supply. Shoe tree for use in a presentation and storage system for a shoe, wherein the shoe tree comprises a front molding (34) which can be inserted into a shoe front part, characterized in that the molding (34) has a recess (36) into which a magnetic element ( 35) is used. Shoe tightener according to claim 13, characterized in that the recess (36) has an opening in the direction of a shoe bottom (41). Method for fixing a shoe (7) with shoe bottom (41), toe, shoe heel (9) and a foot receiving space (6) on a base element (2), which at least partially has a magnetizable or magnetic, metallic surface, using a Magnetic element (5; 35) which in electromagnetic interaction with the metallic surface for fixing the shoe (7) contributes to the base element (2), characterized in that the magnetic element (5; 35) within the foot-receiving space (6) becomes.

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