RU164267U1 - STRUCTURE OF THE SLIDING SYSTEM OF FRAMELESS GLAZING - Google Patents

Abstract

1. The design of the sliding frameless glazing system, including a sash rotatable around the vertical axis, mounted on the side of the side narthex, and sliding sashes, all sashes are frameless, their glass panels are each installed in their own upper and lower profiles of the sash, the design has upper and lower horizontal guides , each of which is made in the form of a figured profile having a base and two parallel side walls, each support has one support of the axis of rotation the pivoting flap and said half shafts are fixed respectively in the upper and lower profiles of this flap; also, the roller bearings of the sliding flaps are installed in each rail to allow the roller bearings to roll in the inner channel of the guide, each sliding flap has four roller bearings pairwise mounted on two vertical geometric axes, while the roller bearings of the first pair are designed for the longitudinal movement of the sliding sash, and the roller bearings of the second pair are simultaneously a ball nirami to rotate the sliding sash when it is at the extreme stop point, each roller bearing of the sliding sash has two independent rollers mounted on a common vertical axis of rotation, which is fixed at one end to the profile of the sliding sash, the other end is free, while in the side wall of each the guide has a groove for the exit of the roller bearings of the first pair to ensure the rotation of the sliding leaf when it is at the extreme stop point, the design is also equipped with means for locking the roller bearings p for

Description

The utility model relates to the field of construction, namely to sliding frameless glazing systems in which sliding shutters are capable of longitudinal movement along the guides installed in the opening and rotate around a vertical axis (swinging the shutter inside the room) when the control stop point is reached. In this application, the term "frameless glazing" is used in the meaning common in the field of construction [see for example, http://www.okna-its.ru/bezramnoe-osteklenie.html], refers to a glazing system without imposts, in which translucent sashes do not have frames around the perimeter, but are fixed only in their own upper and lower profiles, without application of vertical connecting frame profiles. Also, the term "sash" (opening element) in this application equally refers to both a frameless window sash, if, based on size, the system is applicable for glazing balconies and loggias, and to a frameless door sash, if of sizes, the system is applicable for glazing terraces and gazebos.

It is well known that swing glazing systems, in which glass around the perimeter are fixed in frames. If it is necessary to glaze long loggias, several flaps are used, for fixing which it is necessary to install imposts or to fix part of the flaps motionless. The presence of vertical frame elements, as well as imposts, worsen the view of the panorama opening from the loggia.

Sliding glazing systems are well known. In sliding systems, translucent panels are installed in the upper and lower horizontal rails and, when opened, slide to the side. Designs can be frame, and have the above drawback, or frameless, that is, their glass is fixed only in the upper and lower profile. In sliding glazing systems for loggias and terraces, glass panels are installed and moved in parallel planes, and therefore they cannot open the entire opening, because in the open state, all panels are installed parallel to one panel located at the side vestibule. In the closed position, the panels are installed with a slight overlap of vertical edges. In addition to limiting the review, the drawback of sliding systems is the inconvenience of use, and on the upper floors and the insecurity of washing them, because one side of all glass panels is always oriented outward. In addition, the number of panels is limited by the stiffness of the multi-groove profile (so to speak?) Of the guides.

To eliminate these drawbacks, designs were developed and found to have translucent panels, which can not only be shifted along the guides, but rotated 90 degrees around the vertical axis, to the inside, that is, folded “booklet” along the side wall of the loggia. Typically, such systems are frameless. Thus, such designs combine the advantages of both sliding and swinging systems, and at the same time allow opening the opening almost completely. As an example, above is a link to an Internet resource that demonstrates the advantages of the system.

One of these structures is described in European patent EP 0902153. The design of the sliding frameless glazing system presented in the patent contains glass panels, each of which has its own upper and lower profile. Sliding sashes move along the upper and lower rails. Each leaf is moved by means of two pairs of roller bearings. One pair serves exclusively for the longitudinal movement of the sash, the other, in addition, allows the sash to rotate around the vertical axis to set it in a position perpendicular to the glazing plane when the sash reaches the point of extreme break. A special groove is provided in one of the walls of each rail, designed to remove the first pair of roller bearings of the sliding flaps from the inner channel of the rail and to turn these flaps. The patent does not describe a pivoting sash on the side of the side vestibule. The patent also does not describe the mechanism for locking the rollers in the extreme position, but it is obvious to the specialist that the pin system is provided by default. The roller bearings of the wings described in one embodiment have two independent rollers mounted on a common composite axis using an eccentric sleeve, that is, the rollers have parallel geometric axes of rotation. The axis of the supports are fixed to the corresponding profiles of the wings. The disadvantage of the system is the complex construction of the roller bearings and the corresponding configuration of the guide profile, in which the bending of the profile walls themselves serve as a supporting surface for the rollers.

As a prototype, the frameless glazing system design described in international application WO 2013/007611 was selected. This patent describes the design of a frameless glazing system similar to that described above. The swing application is not described in the patent application, but it is obvious to a person skilled in the art that it is present in the structure. A significant difference between the prototype and the analogue described above is the device of the roller support, in which both rollers are mounted on a common axis. In this case, the rollers carry out rolling in the guide channel in the longitudinal grooves of a C-shaped section formed by ribs on the inner surface of the side walls. The presence of narrow grooves of a C-shaped section, covering the rolling surface of the rollers, and restricting the movement of each roller both from above and from below, can lead to jamming of the rollers during operation. A high probability of jamming is also due to the fact that the ribs located between the rollers are support for the upper roller, and therefore are subject to deformation and wear. Another design drawback is the complex system of locking the flaps at the extreme stop point, including an expansion latch made in the form of two combs with counter-oriented protrusions, between which cylindrical recesses are formed to receive a locking element located on the corresponding flap.

The technical problem solved by the utility model is the expansion of the arsenal of tools and the creation of a new improved design of a sliding frameless glazing system with increased reliability. Achievable technical result - preventing the possibility of jamming of the rollers while simplifying the structural elements.

The inventive design of a sliding frameless glazing system includes a sash rotatable around the vertical axis, mounted on the side of the side vestibule, and movable sashes, all sashes are frameless, their glass panels are each installed in its own upper and lower sash profile. The design has an upper and lower horizontal guide, each of which is made in the form of a figured profile having a base and two parallel side walls. In each guide, one support of the axis of rotation of the rotary sash is installed. These half shafts are fixed respectively in the upper and lower profile of this leaf. Also, in each guide, roller bearings of the sliding flaps are installed with the possibility of rolling the roller bearings in the inner channel of the guide. Each sliding leaf has four roller bearings, pairwise mounted on two vertical geometric axes, while the roller bearings of the first pair are designed for the longitudinal movement of the sliding leaf, and the roller bearings of the second pair are simultaneously hinges for turning the sliding leaf when it is at the extreme stop point. Each roller support of the sliding leaf has two independent rollers mounted on a common vertical axis of rotation, which is fixed at one end to the profile of the sliding leaf, the other end is free. At the same time, in the side wall of each guide there is a groove for the exit of the roller bearings of the first pair to ensure the rotation of the sliding sash at its position at the extreme stop point. The design is also equipped with means for locking the roller bearings when the position of the sliding flaps at their extreme stop points. The design differs from the prototype in that the side walls of the rails are internally non-basic, a longitudinal shelf is made on the inner surface of each side wall, the shelves are located at different heights relative to the base of the rail. The concave surfaces of the shelves face each other, and each shelf is a support for one of the rollers of each roller support moving in this guide.

In a preferred embodiment, the design has two means of locking the roller bearings, each of which is installed in one of the rails, and is made in the form of a comb-set comb consisting of elements, one element per sliding leaf. Each comb element is a figured plate fixed to the base of the guide and provided with a protruding pin. At the same time, there is a diametrical groove on the free protruding end face of the axis of the roller support of the second pair of roller bearings, made so that the pins of the comb elements can pass through it during the longitudinal movement of the sliding sash, and preventing its longitudinal movement in the position when the sash is turned relative to the window plane.

In order to better demonstrate the distinctive features of the utility model, as an example, not having any restrictive nature, the preferred embodiment is described below. An example implementation is illustrated by the Figures of the drawings, in which: FIG. 1 - the claimed design of a sliding frameless glazing system, a fragment of the lower part with a spatial separation of the parts, FIG. 2 - the claimed design when the sliding sash is located at the extreme stop point, FIG. 3 is a cross section of a roller bearing.

The design of the sliding frameless glazing system has a pivoting flap 1, which is installed on the side of the side vestibule 2 and sliding flaps 3. All the flaps are frameless, their glass panels 4 are each installed in their own upper and lower profile 5 (leaf profiles). The design has upper and lower horizontal guides 6. Each of the guides 6 is made in the form of a shaped profile having a base 7 and two parallel side walls 8. In each guide 6 from the side of the side vestibule, one support 9 of the axis of rotation 10 of the rotary shutter 1 and said half shafts 10 are fixed, respectively, in the upper and lower profile of this leaf. Also, in each guide, roller bearings 11, 12 of the movable flaps 3 are installed with the possibility of rolling of the roller bearings in the inner channel of the corresponding guide. Each sliding sash has four roller bearings, two of which are installed in the upper guide, the other two in the lower guide. In this case, the roller bearings are installed in pairs on two vertical geometric axes located near the vertical edges of the wings. The roller bearings 11 of the first pair are designed exclusively for the longitudinal movement of the sliding leaf, and the roller bearings 12 of the second pair not only provide longitudinal movement, but at the same time they are hinges for turning the sliding leaf when it is at the extreme stop point. These roller bearings are located on the installation side of the swing leaf.

Each roller bearing of each sliding leaf has two independent rollers 13, between which there is a spacer sleeve. The rollers 13 of one roller support are mounted on a common vertical axis of rotation 14, which at one end is fixed to the profile 5 of the sliding sash. The means for such a fixation is cracker 15, fixed at the base of the sash profile. The other end of the axis 14 is free. To ensure the rotation of the sliding sash, at its position at the extreme stop point, the output of the roller bearings of the first pair through the groove 16 in the side wall of each guide is provided.

The design provides two means of locking the roller bearings, each of which is installed in one of the guides. The locking means is located on the side of the rotary shutter and is made in the form of a stacked comb, consisting of separate elements joined together. Each element of the comb is a figured plate 17, mounted in any suitable way in the base of the guide. Each plate 17 is provided with a pin 18 protruding in the direction of the leaf. On the free protruding end of the axis of each roller bearing of the second pair of roller bearings there is a diametral groove 19. Its dimensions are selected from the condition that the pins 18 can pass through it when the sliding leaf is longitudinally moved. In the position when the sash is rotated relative to the plane of the window, the slot is also rotated relative to the longitudinal axis of the guide, while the pin inside the slot prevents the longitudinal reverse sliding of the sash. From the sash to the sash, the distance between the vertical geometric axes of the pairs of roller bearings decreases in the direction from the side vestibule. The reduction step is equal to the distance between the pins, which in turn is determined from the need to distance the sliding flaps from each other in the "open" position. This allows you to output through one groove 16 of the corresponding guide roller bearings of the first pair of roller bearings of all sliding wings.

Unlike the prototype, the aluminum profile of the guide does not have 8 separate longitudinal grooves for each roller of the roller support on the inner surfaces of the side walls. That is, the walls of the rails are made internally non-basic. Shelves 20 serve as supports for the rollers. The design provides for the presence of two shelves - one per roller. Accordingly, the shelves 20 are located at different heights with respect to the base 7 of the guide. The concave surfaces of the shelves face each other, that is, the rollers, and are the rolling support surfaces for the rollers. On the upper edge of the lateral walls 8 of the guides that are flat outside, channels 21 for installing a brush seal are formed.

The design is equipped with commonly used for these purposes, locking elements and other accessories, which are not shown in the drawings.

In the initial closed state, all the flaps are in the same plane, almost touching the adjacent vertical edges of the glass. Nothing prevents the review of the opening panorama, as the opening is closed exclusively by glass panels. When opening, first turn inward the pivoting sash 1 and set it in the perpendicular plane of the opening of the plane. Then, a sliding leaf adjacent to it is shifted to a vacant place in the guides. The movement is carried out by rolling the rollers on the supporting surfaces of the guide shelves. When the sliding shutter reaches the point of extreme break, it is turned inward and set parallel to the rotary shutter. When the sash is rotated, the roller bearings 11 of the first pair freely exit the groove 16. In the “open” position, the pin 18 of the comb is in the center of the diametrical groove 19 and prevents the sash from rolling back, that is, its position is fixed. Next, this operation is repeated, alternately shifting the flaps and turning them inward. Thus, the opening can be opened almost completely or, if necessary, only partially, by sliding and turning only part of the wings, and the rest only by sliding to the vacant seat.

The described design provides a special case of implementation, in which all the leaves are shifted in one direction. However, all of the above applies to a symmetrical design, when rotary wings are installed on the side of both side vestibules, and accordingly, there are two grooves 16 for the exit of the rollers. Such a design may be especially relevant for its implementation in the construction of a gazebo or terrace.

Due to the fact that each roller 13 has only one abutment surface on the guide and these surfaces are “diagonal” in cross section, the structure is resistant to distortions, which increases its reliability. The possibility of jamming the rollers in the grooves due to their absence is prevented. The use of a relatively simple design of the locking means also increases the reliability of the device as a whole.

Claims (2)

1. The design of the sliding frameless glazing system, including a sash rotatable around the vertical axis, mounted on the side of the side narthex, and sliding sashes, all sashes are frameless, their glass panels are each installed in their own upper and lower profiles of the sash, the design has upper and lower horizontal guides , each of which is made in the form of a figured profile having a base and two parallel side walls, each support has one support of the axis of rotation the pivoting flap and said half shafts are fixed respectively in the upper and lower profiles of this flap; also, the roller bearings of the sliding flaps are installed in each rail to allow the roller bearings to roll in the inner channel of the guide, each sliding flap has four roller bearings pairwise mounted on two vertical geometric axes, while the roller bearings of the first pair are designed for the longitudinal movement of the sliding sash, and the roller bearings of the second pair are simultaneously a ball nirami to rotate the sliding sash when it is at the extreme stop point, each roller bearing of the sliding sash has two independent rollers mounted on a common vertical axis of rotation, which is fixed at one end to the profile of the sliding sash, the other end is free, while in the side wall of each the guide has a groove for the exit of the roller bearings of the first pair to ensure the rotation of the sliding leaf when it is at the extreme stop point, the design is also equipped with means for locking the roller bearings p at the position of the movable flaps at their extreme breakpoints, characterized in that the side walls of the rails are internally non-grooved, a longitudinal shelf is made on the inner surface of each side wall, the shelves are located at different heights with respect to the base of the rail, the concave surfaces of the shelves face each other , and each shelf is a support for one of the rollers of each roller support moving in this guide. 2. The design according to p. 1, characterized in that it has two means of locking the roller bearings, each of which is installed in one of the guides and is made in the form of a comb comb consisting of elements, one element per sliding leaf, each comb element is a curved plate fixed to the base of the guide and provided with a protruding pin, while on the free protruding end of the axis of the roller bearings of the second pair of roller bearings there is a diametrical groove, made possible the passage in it of the pins of the comb elements during the longitudinal movement of the movable sash and preventing its longitudinal movement in the position when the sash is rotated relative to the plane of the window.

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