WO2024062141A1 - Device for a slider with passive magnetic interaction - Google Patents

Abstract

The invention innovatively improves smoothness in the movement of sliding sheets on the guide thereof, since the friction between the sheet and guide produced until now due to the weight of the sheet disappears. This is the case because the sheet is suspended in the air a few millimetres above the guide, since both the guide and the sheet include magnet parts with the particular feature that the sides facing each other of the guide and sheet magnet parts (the parts) also have the same facing polarity. This produces a repulsion force therebetween that vertically separates them, where the space between them measures the aforementioned few millimetres. This separation is kept constant along the entire length of the sheet, and therefore it is also maintained when said sheet slides over the guide. Said "levitation" effect of the sheets can be achieved in several ways based on the way in which said magnets are positioned, the way in which they are grouped and their shape. The invariable constraint in all the types presented is that the magnet parts are positioned with their cross section symmetrical with respect to the vertical axis of the cross section of the sheet/guide assembly.

Description

DESCRIPTION OF SLIDING DEVICE WITH PASSIVE MAGNETIC INTERACTION. SECTOR OF THE TECHNIQUE The present invention is located fundamentally in the sector of carpentry for construction. And more specifically in the carpentry of sliding doors and windows. BACKGROUND OF THE INVENTION Currently, sliding doors and windows in homes and buildings in general have the handicap of not maintaining the smoothness of their opening and closing movement over time when sliding along their guides. The mechanism that allows said movement consists of a fitting located at the top or bottom in which one or more wheels are housed; wheels that allow the sliding of the door or window leaf by rotating them on a guide attached to the lower or upper frame of said carpentry element. That is why, due to the weight that these wheels must support over time or the lack of continued use, the wheels gradually deform, losing their initial shape of perfect circumference, which translates into greater difficulty for them to rotate. softly and allow the movement for which they have been designed comfortably. EXPLANATION OF THE INVENTION Our invention improves, in an innovative way, the smoothness of the movement of the sliding leaves on their guide since the friction between the leaf and the guide that until now occurred due to the weight of the leaf completely disappears. And this is because the leaf is suspended in the air a few millimeters above the guide by incorporating magnet pieces in both the guide and the leaf with the particularity that the facing faces of the guide and leaf magnet pieces ( the pieces) have the same polarity also facing each other, which produces a repulsive force between them that separates them vertically, leaving that space between them of those few millimeters mentioned. That separation remains constant along the entire length of the blade, and therefore is also maintained when said blade slides on the guide. This effect of “levitation” of the leaves can be achieved in several ways depending on the way in which said magnets are placed, the way they are grouped, and their shape. The invariable condition in all the types to be exposed is that the magnet pieces are placed keeping their cross section symmetrical with respect to the vertical axis of the cross section of the leaf/guide assembly. To avoid deterioration and breakage, the magnets will be protected on all their external surfaces or in parts of them with aluminum or other material. Type A: Blade and guide magnets both sharing the same vertical axis of their cross section seen along the path of the blade and with the orientation of the positive pole (+) upwards in the guide magnet and downwards in the drive magnet. the blade, thus leaving the maximum effect of vertical repulsion on their facing faces. To avoid the horizontal displacement that will cause repulsion between the guide and sheet magnets, small balls of polyester or similar type material will be housed on both sides of the sheet in said lower part where the set of magnets is located. Spheres with the necessary diameter to allow the very smooth sliding movement of the blade in its path and at the same time not allow horizontal displacement perpendicular to said path in that lower part of the blade due to the effect of the aforementioned repulsion, thereby achieving that maintain its transverse vertical axis common with that of the guide throughout its travel path. Obviously, the balls will be prevented from moving horizontally perpendicular to the course by having the leaf itself on one side and another wall on the other side in the frame along its entire length. Type B: To avoid the use of balls of the previous shape, the magnets or groups of them will form a “V”, a “U” or a mixture of them to prevent, as a result of this shape, the horizontal transverse lateral displacement of the sheet. with respect to the guide by not allowing this displacement due to the repulsion that occurs in the middle and upper areas of said “V” or “U” shape or a mixture of them. In this case the Magnet orientations will remain as in type A. The pole

facing up on the guide magnets and facing down on the blade magnets. Type C: Variation of type B in which the orientation of the magnets will depend on the inclined plane (and which in the cross section will be seen as an inclined line with a certain angle) in which the faces of the guide magnets face each other. the leaf ones. In the specific case of the “V” shape with a constant angle of the plane of confrontation of the sheet magnets with those of the guide, the orientation of the poles will continue to maintain the confrontation of the + poles of the two magnets, so now The positive pole of the guide will not be up and that of the blade down, but rotated 90 degrees and adding or subtracting (depending on the side of the V) the angle of the “V” with respect to the horizontal axis, which will determine that the + poles follow facing each other in the two magnets in the same way as in type A, except that in this type C the entire assembly that forms the plane of confrontation of the magnets and their positive poles is rotated. To conclude, indicate that referring to the positive pole (+) to detail each type does not imply ruling out also doing so facing the negative pole (-) of the magnets. PREFERRED EMBODIMENT OF THE INVENTION The exposed invention will be produced mainly by incorporating it into aluminum or PVC carpentry elements intended for enclosures and interior compartmentalization in buildings.

Claims

CLAIMS 1. Device for sliding sliders effortlessly incorporated into sliding systems characterized in that said elements are incorporated with a set of pairs of facing magnets, housed in line according to the direction of movement of the slider, housed, some in the guide where the slide and others run on the sliding leaf itself, the magnetic poles of each guide magnet being oriented with respect to the one housed in the leaf so that their facing surfaces are of the same polarity, and this throughout the entire path of the leaf/guide assembly . The magnets will be covered - on all or part of their surface - with another material. 2. Device according to claim 1 in which the pairs of magnets are housed, some in the lower part of the sliding leaves and others in the upper part of the guide through which said leaf moves. 3. Device according to claim 2 in which the pairs of magnets in the sheet and guide share the same vertical axis of their cross section seen along the path of the sheet, with the orientation of the positive pole (+) upwards in the guide magnet. and down on the magnet sheet. On both sides of the set of magnets there will be small balls, spheres that will be in lateral contact both on one side with the leaf itself and on the other and also below with the walls of the frame itself. 4. Device according to claim 2 in which the meeting line of the two groups of guide/leaf magnets in its cross section according to the path of the guide is “V” shaped, with the orientation of the positive pole (+) upwards. in the guide magnet and downwards in the leaf magnet 5. Device according to claim 2 in which the meeting line of the two groups of guide/leaf magnets in its cross section according to the path of the guide has the shape of " U”, with the orientation of the positive (+) pole facing up on the guide magnet and facing down on the blade magnet. 6. Device according to claim 2 in which the meeting line of the two groups of guide/leaf magnets in its cross section according to the guide path has a mixed “V” and “U” shape, with the orientation of the positive pole (+) upwards in the guide magnet and downwards in the magnet of the sheet. 7. Device according to any of claims 4, 5 and 6 in which the positive pole is not always up in the guide magnets nor is it always down in the blade magnets. The positive poles are still facing each other because they now rotate both the same degrees (one in one direction and one in the opposite) in the plane of their cross section according to the route of the guide, to adapt to the different inclination that the meeting line of said cross section has in its route. already referred to above. 8. Device according to claim 1 in which each pair of magnets are housed, one on the lower face of the upper part of the upper horizontal frame of each sliding leaf, and another on the upper face of the guide through which said leaf runs, guide also located in the upper part of the carpentry, the latter magnets always remaining immediately below those. This set of pairs of magnets have the magnetic poles of each guide magnet with respect to the one housed just above it in the horizontal frame of the sheet with the same polarity facing each other throughout the entire length of the sheet/guide assembly of the carpentry. 9. Device according to claim 8 in which the meeting line of the pairs of guide magnets/leaf in any of its transversal sections to the path of the leaf is a horizontal line. The orientation of the positive pole is up on the guide magnets and down on the blade magnets. Also seen in cross section, on both sides of the magnets there is a ball that is always in lateral contact with the leaf on one side and with the frame on the other. The balls are repeated along the length of the blade and also have a side wall at the beginning and end of it. 10 ^. Device according to claim 8 in which the meeting line of the guide/leaf magnet pairs in any of its cross sections has a "V" shape, with the orientation of the positive pole upwards in the guide magnet and downwards in the magnet of the sheet 11. Device according to claim 8 in which the meeting line of the pairs of guide/leaf magnets in any of their cross sections is “U” shaped, with the orientation of the positive pole upwards in the guide magnet and downwards in the leaf magnet. 12. Device according to claim 8 in which the meeting line of the two magnets - or groups of magnets - guide/leaf in any of its cross sections has a mixed shape between "V" and "U", with the orientation of the pole positive upward on the guide magnet and downward on the blade magnet. 13. Device according to any of claims 10, 11 and 12 wherein the positive pole is not always just above on the guide magnets nor is it always just below on the blade magnets. These positive poles do continue facing each other, in each pair of guide/leaf magnets, but now the two poles are rotated in the plane of the cross section by the same degrees (one in one direction and one in the opposite) to adapt to the different inclination that the meeting line of said cross section already referred to above takes along its route. 14. Device according to any of claims 3 to 7 and 9 to 13 in which the pole facing the magnets is the negative pole.