FI91310C - Glide System - Google Patents

Description

i 91310

SLIDING ELEMENT SYSTEMMX - GLIDELEMENTSYSTEM

The invention relates to a sliding element system as defined in the preamble of claim 1.

Sliding element systems in which the sliding elements are movable partitions are already known, for example, from DK 155 195, SE 427 683 and EP 0 437 029. Such a typical system includes a rectangular sliding element having a first side and a second side which are substantially parallel to each other, and guide wheels attached to the sliding element on the first side and the second side. Each guide wheel includes a number of wheels and one shaft on which the wheels are mounted 15 in succession as separate wheels. The shaft is fixed perpendicularly to the first and / or second side of the sliding element, the rotating planes of the wheels being substantially perpendicular to the plane of the sliding element, the axis of rotation of the wheels being respectively substantially parallel to the plane of the sliding element. Further, the system includes a pair of rigid conductor profiles comprising a housing-like first conductor profile on the first side of the slider and a housing-like second conductor profile on the second side of the slider. The conductor profile includes conductors parallel to the conductor profile combined with the inner walls of the box-like conductor profile to guide and support the conductor hydraulics within the conductor profile. Of the brackets, at least one of the first brackets 30 is in contact with one side of the first wheel and the second bracket is in contact with the opposite side of the second wheel relative to the contact of the first wheel and the first bracket. The brackets are planar support surfaces on which 35 guide wheels are supported. The support surfaces are in alternating contact with the overlapping wheels so that one support surface supports one side of one wheel of the guide gear 2 while the other support surface supports the opposite side of the other wheel. With such an arrangement, the advantage is achieved that the guide profile can have angles through which the wheels of the sliding element 5 can be easily transported.

The problem with these previously known systems, however, is that their sliding elements are intended to function as suspended or otherwise vertical, so that they do not include arrangements 10 which would prevent their lateral or vertical movements in other systems than those known in the art. in an upright position.

A further problem with previously known systems is that they are not suitable for objects in which the sliding elements are subjected to a dynamic variable load in a direction perpendicular to the sliding element. Such a load situation is e.g. in the case of balcony glazing systems, in which the sliding elements, i.e. the glass elements, are subjected to 20 varying loads due to the wind pressure, which also causes disturbing noise when the glass elements flutter and rumble against the guide profiles. With the rotation arrangements of the known systems, it is not possible to provide such a lateral (perpendicular to the plane of the element) support of the element that the gaps between the rotations are as small as possible, for example to prevent oscillations caused by wind pressure. Em. the wheel arrangements according to the publications also do not provide any support against the deflection of the element caused by the wind pressure. Elimination of oscillation and excessive deflection is particularly important when a sliding element is formed from a glass sheet. If the support allows excessive deflection and high amplitude when the element oscillates, the glass sheet 35 may break as a result. If there are several glass sheets next to each other in the system, as in the case of balcony glazing, for example, the large amplitude of the element affects the adjacent glass sheets, reinforcing their oscillations, which can lead to breakage and the like.

The object of the invention is to eliminate the above-mentioned drawbacks.

It is a further object of the invention to provide a sliding element system which can be mounted in any desired position without changing parts, and which at the same time has the advantage that the guide profile can have angles through which the sliding element wheels can be easily transported so that the sliding element can be transported. through.

It is a further object of the invention to provide a sliding element system which is made completely robust and silent despite the lateral loads on the sliding elements, e.g. varying loads due to wind pressure.

The system according to the invention is characterized by what is stated in claim 1.

According to the invention, the support has a groove and the cross-sectional shape of the circumference of the wheel cooperating with the support is adapted to substantially correspond to the shape of the support groove, or alternatively the wheel has a groove and the cross-sectional shape of each of the cooperating support the wheels, together with the corresponding supports of the guide profiles, are sliding elements in all other directions except in the direction of movement defined by the guide profile and the supports 30, which are held and profitable.

Thanks to the invention, the sliding element system can be installed in any position, because the supports support the guide wheels in all directions except the direction of movement, without interfering with the operation of the system. By sliding element is meant any structural element which is arranged to be displaceable on the basis of guide profiles. The sliding elements can be mounted in a vertical position, in a horizontal position or in any position, and the sliding elements can slide vertically, horizontally or in any other direction, depending on the application. Regardless of the position, the sliding elements always rest equally firmly on the guide profiles. One special application is balcony glazing systems, in which the balcony is insulated from the outside air by means of movable and openable 10 glass elements. The arrangement according to the invention gives the element a rigid support on both sides thereof, eliminating the deflection. Elimination of oscillation and excessive deflection is particularly important when the sliding element is formed from a glass sheet. The support 15 according to the invention does not allow excessive deflection or a large amplitude when the element oscillates, whereby the glass sheet cannot break as a result.

In one application of the system, the cross-sectional shape of the groove included in the support grain is concave pyo-20. The cross-section of the contact surface of the circumference of the wheel in contact with the groove is convex and adapted to fit the groove. The walls of the trough-like groove extend around the circumference of the surrounding wheel at the point of contact over the entire point of contact between them and extend to the sides of the 25 wheels on both sides. The circular appearance of the wheels is advantageous, especially in sliding element systems, such as balcony glazing systems, in which the guide wheelsets have to be touched by hand when installing and opening the elements. Touching the round wheels then feels comfortable.

In one embodiment of the system, the cross-sectional shape of the trough-shaped groove included in the wheel is concave round and the cross-sectional shape of the support 35 in contact with it is convexly round and adapted to fit the wheel groove. In this case, the trough-like groove of the wheel surrounds the support.

5,91310 In one embodiment of the system, the support includes at least two surfaces that form an angle with each other. The contact surface of the wheel has a corresponding angular shape.

5 In one application of the system, the support is a flange-like rib perpendicular to the axis. The wheel includes two flanges with a groove between them that is adapted to receive the rib inside.

In one embodiment of the system, two guide wheelsets are attached to each side of the sliding element at a distance from each other, the first guide gear and the second guide gear so that the second guide gear on each side is mutually aligned and the guide rails on the same side are common. The first sprocket has a smaller number of wheels than the second sprocket. The axis of the first sprocket is shorter than the axis of the second sprocket. Conductor profiles are enclosure profiles that are open on one to 20 sides. The walls of the conductor profiles include openings which are aligned in each of the conductor profiles and arranged in such a way that the conductor wheels are easily removed from the guide of the conductor profiles through the opening. The installation of sliding elements is a talldin help-25 poa. The system further includes a cover with which the opening in the wall of the guide profile can be partially covered so that when the cover is installed as a partial cover of the opening, an outer wheel on the shaft of the second guide gear rests on the guide. Correspondingly, when the first guide gear is at the opening, the first gear can be removed out of the opening without obstructing the cover, so that the sliding element can be turned so that the axis of the second guide gear is hinged-35 about the axis around which the turning takes place.

In one embodiment of the system, the first guide gear comprises at least two wheels and the second guide gear comprises at least one Pyora more than the first guide gear.

In one embodiment of the system, the lid is made of a flexible material, such as plastic, and is provided with retaining members which are integral with the lid to secure the lid to the edges of the opening. Such a cover can be easily removed and attached without tools.

The invention will now be described in detail with reference to the accompanying drawing, in which Figure 1 shows an embodiment of a sliding element system according to the invention with one sliding element mounted on guide profiles cut vertically at the first guide gear; Fig. 2 shows a corresponding vertical section of the system of Fig. 1 at a second guide wheel; Figures 3-6 schematically show four different applications of the shapes of the wheels and supports; Figure 7 is a side view of the system of Figures 1 and 2 with the first guide rail at the openings in the walls of the guide profiles; Fig. 8 shows the system 25 of Figs. 1, 2 and 7 seen from the side with the second guide gear at the hinge point; Fig. 9 is a vertical sectional view of the system of Figs. 1, 2, 7 and 8 in a situation where the second conductor gear is at an opening 30 in the wall of the conductor profile; Fig. 10 is a vertical sectional view of the system of Figs. 1, 2 and 7 to 9 in a situation where the first conductor gear is at an opening in the wall of the conductor profile; Figures 11 to 17 show various applications of the sliding element system according to the invention; 7 91310

Figures 1, 2 and 7 to 10 show the same sliding element system according to the invention illustrated in different sections from different directions.

Figure 1 is a vertical cross-section 5 of an application of a sliding element system in which the sliding element system is a balcony glazing system. The sliding element 1 here comprises a tempered glass plate 29.

The laminated glass sheet is also suitable for use as a glass element in a balcony glazing system. The sliding element system 10 most preferably comprises several successive Liu elements 1, although only one such sliding element 1 is discussed in Figures 1 to 9.

The sliding element 1 is rectangular, in which it comprises mutually parallel first side 2 and second side 3. In this application, the first side 2 of the sliding element 1 is its upper side and the second side is its lower side, as shown in Figures 1, 2, 7 and 8. visible when. The edges of the first side 2 and the second side 3 of the glass sheet 29, i.e. the upper edge and the lower edge, are attached to elongate frame profiles 30 extending along the length of the edge of the glass sheet 29. The frame profiles 30 will be described in more detail above with reference to Figure 9.

Attached to the first side 2 and the second side 3 of the sliding element 1 are guide springs 4. Figure 25 1 shows two such guide sprockets 4, which are at the same point in the sliding element 1 with its upper and lower sides. The guide gear system 4 here comprises two wheels 6 and 7. The wheels 6 and 7 are mounted successively concentrically on the shaft 9 so that they can rotate freely 30 independently of one another. In Fig. 2, on the other hand, a second guide gear 5 is attached to each side 2 and 3 at the same distance from the first guide gear 4, preferably at the angles of the slider 1, to each side 2 and 3 (see Fig. 2).

35 also together (pictures 7 and 8). This second guide wheel-t65n 5 comprises three wheels 6, 7 and 8. The wheels 6, 7 and 8 are mounted successively concentrically on a straight shaft 8 so that the wheels can rotate freely separately and the overlapping wheels can rotate in different directions. . The shaft 9 is a straight bolt fixed by a screw connection directly to the frame 30 of the frame-5 in line with the glass plate 29. In this case, the weight of the glass sheet 29 causes only a tensile load on the shaft 9 and not a bending load.

The bearing of the wheels 6, 7 and 8 on the shaft 9 is arranged so that there is a thin smooth bearing plate made of stainless material between the abutment surfaces of the sides 10 to reduce friction. The wheels 6, 7, 8 are preferably made of a plastic material, e.g. a POM injection molded plastic wheel.

The system further comprises a pair of conductor profiles-15, 11. The conductor profiles 10 and 11 are fixedly mounted on a fixed structure. The first guide profile 10 is on the first side 2 side of the sliding element 1 and the second guide profile 11 is on the second side 3 side of the sliding element 1. The conductor profiles 10 and 11 are 20 identical housing-like profiles, preferably made of aluminum by extrusion in a conventional manner. The guide profiles 10 and 11 comprise brackets 12, 13, 14 parallel to the guide profile, which function to support and guide the guide wheelsets 4 and 5. In Fig. 1, the guide wheelset 4 with two wheels 6 and 7 rests on the guide profiles 10, 11 by supporting the two supports 12. and 13 within the conductor profile 10, 11. The first wheel 6 rests on the first bracket 12 and the second wheel 7 rests on the second bracket 30. The guide profile 10 and 11 also have a third bracket 14 which is adjacent to the third wheel 8 of the three-wheel guide wheel 5, as shown in Fig. 2. the supports support the different wheels diagonally alternately on opposite sides, 35 the guide wheelsets 4 and 5 being firmly supported on the guide profiles 10 and 11. The wheels 6, 7, 8 of each guide wheelset 4 and 5 together with the respective supports 12, 9 91310 13, 14 are arranged support the sliding element 1 in all other directions except in the direction of movement defined by the guide profile 10, 11 and the supports. In other words, the sliding element 1 5 only moves in the direction of the guide profiles 10 and 11. The guide gears 4 and 5 cannot move in the direction of the axis 9. Loads perpendicular to the sliding element 1, e.g. wind load in balcony glazing, do not in any way impede the passage of the sliding elements 10 on the guide profiles and a variable load such as a wind load does not cause any oscillation. The system works as well under load as when loaded in any direction, regardless of whether the system is mounted horizontally, vertically-15 or inclined.

Different flanges and grooves can be formed in the guide profiles 10 and 11 for different purposes. The guide profile 10, 11 comprises a groove 100 with brush brushes 101 and a fastening flange 102 with water plates 103. Mounting grooves 104 are formed in the inner corners of the guide profile 10, 11, by means of which and by means of suitable mounting members, such as pins, screws, etc., the profiles can be fastened transversely to each other directly and angled joints can be made.

It can be seen from Figures 1 and 2 that, in the exemplary case, the brackets 12, 13 and 14 have trough-like grooves 15, 16 and 17. It can be seen from the cross-section of the grooves 15, 16 and 17 that the shape of each groove is concave. Respectively, the cross-sectional shape of the circumferential contact surface 18 of the wheels 6, 7 and 8 in rolling contact with the groove is convex and fits within the corresponding groove. The walls of the trough-like groove extend around the circumference of the circumferential wheel at the point of contact over the point of contact between them and extend to the sides of the wheel on both sides. The shape of the grooves is also advantageous from the point of view of cleaning, since dirt and debris do not accumulate in the grooves, which could impair the co-operation of the guide wheels and the grooves 10.

The weight of the element 1 is made suitable for all the wheels 6, 7, 8 on each side 2 and 5 3 and for all the supports 12, 13, 14 of the guide profiles 10 and 11, respectively, by means of a suitable distance between the guide profiles 10, 11.

Figures 3 to 6 show alternative examples to the application shown in Figures 1 and 2 of how the wheels 6, 7, 8 and their corresponding profile supports 12, 13, 14 can be shaped in order to achieve the object of the invention. Figures 3 to 6 schematically show from the side only one Pyora detached from the system as a whole.

In Fig. 3 the wheel 6, 7, 8 comprises a groove 19, the cross-sectional shape of which 15 and the cross-sectional shape of the cooperating support 12, 13, 14 are adapted to substantially correspond to each other so that the cross-sectional shape of the groove 19 of the wheel 6, 7, 8 is concave and the cross-sectional shape of the contacting bracket 20 12, 13, 14 is convexly circular and selectively fitted to fit the groove of the rotor.

In Figure 4, the support 12, 13, 14 comprises two surfaces 20 and 21 which form an angle α with each other. The contact surface 22 of the wheel 6, 7, 8 has a corresponding angular shape. The contact surfaces 20 and 21 of the support 12, 13, 14 open here in a V-shape inside the profile.

In Figure 5, the support 12, 13, 14 comprises two surfaces 20 and 21 which form an angle α with each other. The contact surface 22 of the wheel 6, 7, 8 has a corresponding angular shape. The contact surfaces 20 and 21 of the support 12, 13, 14 are in cross-section on the sides of the wedge-shaped flange.

In Figure 6, the support 12, 13, 14 is a flange-like rib projecting perpendicularly from the wall of the profile. The wheel 6, 7, 8 comprises two flanges 23, 24, between the grooves 35 of which there is a groove 25 adapted to receive the rib inside.

Figures 7 and 8 show the same sliding element 1, on which 11 91310 two guide wheelsets, a first guide gear 4 and a second guide gear 5, are fastened to each side 2, 3 of each other at a distance. The first guide wheels 4 are centrally located on each side 2 and 3. as also shown in Figure 1.

Likewise, the second guide wheels 5 on each side 2 and 3 are mutually aligned, as also shown in Fig. 2. The guide wheels 4 and 5 fastened to the first side 2 by the brackets 9 operate under the control of the same guide profile 10 10 and the guide wheels 4 and 5 fastened to the second side 2 by the shafts 9 operate under the control of the same guide profile 11. As shown above, the first sprocket 4 has two wheels and the second sprocket 5 has three wheels, and the shaft 94 of the first sprocket is shorter than the shaft 95 of the second sprocket. Thus, the extent of the first sprocket 4 is lower than the span of the second sprocket 5. The walls of the housing-like conductor profiles 10 and 11 include openings 26 located at each of the conductor profiles 10 and 11 and arranged so that both the first conductor gear 4 and the second conductor gear 5 can be removed through the opening 26 out of the guide profiles, facilitating the installation of the slide elements 1. for the support of the conductor profiles 10 and 11 25. The opening 26 is then covered by a cover 27, shown in Figures 7, 9 and 10. The cover 27 is supported at the edges of the opening 26 by holding members 28 formed in the cover and integral with the cover. The function of the cover 27 is to partially cover the opening 26, so that the cover includes a second opening 35, from which the two-wheeled first guide gear 4 fits out when the sliding element 1 is slid to such a position that the first guide gear 4 has the guide profiles 26. , as in the situation of Figures 7 and 10 35. At the same time, the three-wheeled second guide gear 5 is preferably at a hinge point defined by the hinge arrangement 36, where the shaft 95 of the guide gear 5 12 locks in place with respect to the guide profiles 10, 11 when the sliding element 1 Said hinge arrangement 36 is preferably the one described in the same applicant's Finnish patent application FI-914848 (Finnish patent no. 89532, granted October 11, 1993), to which reference is made herein.

It can be seen from Figure 9 that when the cover 27 10 is mounted in the opening 26, the outermost third wheel 8 on the shaft 95 of the second guide gear 5 rests on the cover 27 so that the second guide gear 5 not intended to come out of the opening 26 in use can be moved. past the opening 26 without inadvertently coming out of the opening.

Figure 9 also shows a preferred shape of the frame profile 30. The frame profile 30 is preferably a profile made of aluminum by conventional extrusion. A preferred feature 20 of the shape of the frame profile 30 shown is that the thickness of the glass to be mounted on the frame profile can be selected according to the particular need. The frame profile 30 of the arms comprises a first flange 31 with a abutment surface 32 parallel to the glass plate 29 to be mounted, against which the edge area of the glass plate rests on the other side 25. The frame profile 30 further includes a second flange 33 perpendicular to the first flange 31. The frame profile 30 is mounted on a glass sheet 29 such that a separate triangular glazing bead profile 34 with two outer surfaces perpendicular to each other 30 is placed against the glass sheet and to the second flange 33, the glass sheet remaining in place in the groove between the first flange 31 and the glazing bead profile 34. The glazing bead profile 35 of Figure 9 is a housing profile formed from aluminum by extrusion. The profile 34 can preferably be attached to the glass sheet by gluing and to the second flange 13 91310 by gluing and / or riveting, e.g. pop-niiteil-lå. The second flange 33 of the frame profile 30 is arranged in such a way that by shifting the position of the glazing bead profile 34 and its attachment relative to the second flange 33 to the frame profile 5, glasses or laminated glass of different thicknesses can be attached. The glass is also easy to replace if necessary.

Figure 11 shows an embodiment of the sliding element system according to the invention, in which the sliding elements 1 included in the system are glass elements protecting the balcony and insulating 10, which rest on horizontal guide profiles 10 and 11. The first or upper guide profile 10 is attached to the balcony slab of the upper balcony. The second or lower guide profile 11 is attached to the railing of the lower balcony. The conductor profiles 10, 11 form an angle in the corner of the balcony.

Since the guide wheels are arranged in elements as described above, e.g. according to Figures 1-10, the glass elements can be easily transported through the corner and opened at the desired point. The passage of the elements 1 is effortless and they are firmly supported on the conductor profiles in accordance with the invention.

Figures 12 and 13 show embodiments of the invention in which the sliding element system is a skylight system in which the guide profiles 10 and 11 are mounted 25 in a partly vertical and partly inclined position and the glass elements 1 can be moved and opened as described in connection with Figures 7 and 8. The glass elements 1 can be lowered by selling the guide profiles or, as in Fig. 13, bundled under the eaves when the glasses 30 are desired to be set aside.

Figures 14 and 15 show an embodiment of the invention in which the sliding element system comprises a sliding door consisting of a plurality of sliding door elements 1. The guides 10 and 11 comprise a vertical portion and a horizontal portion 35 at right angles to the vertical portion extending a certain distance from the vertical portion påin.

14

When opening the door, the sliding door elements 1 can be bundled as shown in Fig. 15 to hang on the horizontal part of the guide profiles of the side panels.

Figures 16 and 17 show another embodiment, in which the sliding element system according to the invention is a boat sliding cover, by means of which an open boat can be provided from a closed boat by sliding the windscreen and roof elements 1 on guide bars 10 and 11 to the rear of the boat roof.

10 Only a few examples of sliding element systems are described in connection with Figures 1-17. In fact, only the imagination of the designer sets limits on the objects in which it is advantageous to use the sliding element system according to the invention.

In principle, a similar system according to the invention and the same components can be used to implement a wide variety of sliding element systems in which the position and direction of movement of the elements do not affect the operation of the system. The sliding elements can be windows, doors, glass doors, mirror doors, shower walls, walls, partition panels, roof elements, canopies, hatches, etc. The various sliding elements can be used in residential and industrial buildings, land vehicles and land vehicles.

The invention is not limited to the application examples presented above only, but many modifications are possible while remaining within the scope of the inventive idea defined by the claims.

Claims (8)

15 91310 A sliding element system comprising - a rectangular sliding element (1) having a first side (2) and a second side (3) which are substantially parallel to each other; - guide wheelsets (4, 5) attached to the sliding element on the first side (2) and the second side (3), each guide wheel (4, 5) 10 comprising a plurality of wheels (6, 7, 8) and one shaft (9). ) in which the wheels are mounted successively as separate wheel rims, and which shaft is fixed perpendicularly to the first and / or second side of the slide element, the rotation planes of the wheels (6, 7, 8) being substantially perpendicular to the plane of the sliding element (1). the axis of rotation is correspondingly substantially parallel to the plane of the sliding element; - a fixed pair of guide profiles (10, 11) comprising a housing-like first guide profile (10) on the first side (2) side of the sliding element and a housing-like second guide profile (11) on the side of the second side (3) of the sliding element, and a guide profile (10) , 11) include guide profile parallel supports (12, 13, 14) connected to the inner wall of the housing-like guide profile 25 for guiding and supporting the guide wheels within the guide profile, of which at least one first support (12) is in contact with one side of the first wheel (6) and the other 13) is in contact with the opposite side 30 of the second wheel (7) relative to the contact of the first wheel and the first support, characterized in that the support (12, 13, 14) comprises a groove (15, 16, 17) and a wheel (6) cooperating with the support 7, 8) the cross-sectional shape of the circumference is adapted substantially to the shape of the groove of the support, or alternatively p yoråån (6, 7, 8) belongs to the groove (19; 25) and the cross-sectional shape of the cooperating support (12, 16 13, 14) are substantially adapted to the shape of the groove of the wheel, the wheels (6, 7, 8) of each guide wheel set (4, 5) together with the guide profiles (10, 11) with the respective supports (12, 13, 14) 5 are sliding elements (1) in all other directions except those which are held and supported in the direction of movement defined by the guide profile (10, 11) and the supports. A system according to claim 1, characterized in that the cross-sectional shape of the groove (15, 16, 17) belonging to the support (12, 13, 14) is circular and concave with the circumferential contact surface of the wheel (6, 7, 8) in contact therewith. (18) The cross-section is convexly round and fitted to fit the groove. System according to Claim 1, characterized in that the cross-sectional shape of the groove (19) of the wheel (6, 7, 8) is concave and the cross-sectional shape of the support (12, 13, 14) in contact with it is convex and adapted to fit the wheel. in the groove. A system according to claim 1, characterized in that the support (12, 13, 14) comprises at least two surfaces (20, 21) which form an angle (a) with each other; and that the contact surface (22) of the wheel (6, 7, 8) has a corresponding angular shape. System according to claim 1, characterized in that the support (12, 13, 14) is a flange-like rib perpendicular to the axis (9); and that the wheel (6, 7, 8) comprises two flanges 30 (23, 24) with a groove (25) between them, which is adapted to receive a rib inside. System according to one of Claims 1 to 5, characterized in that two guide sprockets (4, 5) and a second guide sprocket are fastened at a distance from each other (2, 3) to each side (2, 3) of the sliding element (1). (5) such that the second conductor gear (5) on each of the 17 91310 sides is mutually aligned and the wire depressors (4, 5) on the same side are cooperating with the same conductor profile (10 or 11); that the first conductor gear (4) has a smaller number of wheels than the second conductor gear (5), and the axis (94) of the first conductor gear is shorter than the axis (95) of the second conductor gear; that the conductor profiles (10; 11)) are housing profiles and their walls include openings (26) which are aligned in each conductor profile and are arranged so that the conductor hydraulics (4; 5) are removable from the control of the conductor profiles through the opening; that the system includes a cover (27) with which the opening (26) can be partially covered so that when the cover partially covers the opening (26), the outermost wheel (8) on the shaft (95) of the second guide ridge 15 (5) rests on the second guide ridge (5) when passing through the opening (26) and with the first guide ladder (4) at the opening (26) it can be removed from the opening (26) without blocking the cover (27) to turn the sliding element (1) 20 as the hinge axis of the second guide ladder (5) . A system according to claim 6, characterized in that the first guide gear (4) comprises at least two wheels (6, 7) and the second guide spring (5) comprises at least one wheel more than the first guide ring (4). System according to Claim 6 or 7, characterized in that the cover (27) is made of a flexible material, such as plastic, and is provided with holding members (28) which are equal to 30 pieces of the cover for fixing the cover to the opening ( 26) to the edges. 18