RU2466258C2 - Sliding and fixation device and system of balcony glazing equipped with this device - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: sliding and fixation device (1) for fixation of position of a glass panel (5), moved along upper and lower rails, at the specified angle relative to an upper rail (7), besides, the specified upper rail (7) has an upper side (73), a foot (70), an inner side (75) and an outer side (76), at the same time on the upper edge of the glass panel by means of an upper support bar (4) there are two upper guide elements (2; 2' and 2, 2") connected as capable of sliding along the upper rail (7), and on the lower edge of the glass panel by means of a lower support bar (300) there are two lower guide elements (3; 3' and 3, 3") connected as capable of sliding along the lower rail (8), so that the glass panel (5) is fixed between the specified lower support bar (300) and the upper support bar (4), at the same time at least the upper support bar (4) stretches from one end of the glass panel (5) to the other end as capable of rotation and fixation at the angle relative to the upper rail (7), differing by the fact that each upper guide element (2; 2', 2; 2") has a shape of a hemisphere and is arranged in the form of a fixing element by means of its connection to the upper support bar (4), fixed on the upper part of the glass panel (5) by means of the rigid fixation, which prevents mutual rotary movement of the upper support bar (4) and the upper guide element (2), at the same time a counter element (20) of the specified upper guide element (2), serving as a fixing element, is formed by a hole (20) in the form of a circle segment arranged on a shelf (200), so that the horizontal plane stretching through the specified hole, is arranged approximately at the half of height of the specified upper guide element (2), at the same time each upper guide element (2', 2") of each pair of upper guide elements (2) is fixed to the upper support bar (4) at the end of the support bar and simultaneously at the end of the upper edge of the glass panel.

EFFECT: design simplicity.

31 cl, 14 dwg

Description

FIELD OF THE INVENTION

The invention relates to a sliding and locking device in accordance with the introductory part of paragraph 1 of the claims for fixing the position of the glass panel, made with the possibility of movement along the upper and lower rails, at a given angle relative to the upper rail.

The invention also relates to a balcony glazing system in accordance with the introductory part of paragraph 19 of the claims.

State of the art

Glass panels surrounding glazed balconies should be removable, for example, due to the need for washing or changes in weather conditions. For this purpose, the glass panels of the balcony must be moved to an appropriate place on the balcony (usually near the side wall of the balcony) and rotated or fixed at an angle of 90 degrees or more relative to the upper and lower rails of the balcony glazing system.

In prior art glazing systems for balconies, sliding and fixing systems for glass panels typically include upper and lower rails along which panels can be moved. To move the glass panels along the rails, guide elements are arranged inside the upper and lower rails, and separate fixation devices are provided for fixing the glass panels in the desired location. Several types of locking devices are known, but they are usually based on the principle that the locking element, in the form of a stud or disk, comes into contact with its counter element when the glass is rotated to the desired angle relative to the upper rail.

The main disadvantage associated with the fixation devices of known balcony glazing systems is the small permissible deviations with respect to any irregularities in the balcony surfaces of the glass guide elements that slide inside the upper rail and the fixation devices, resulting in a greater need for maintenance and poor functioning. The currently used devices for sliding and fixing the glass panels of the balcony work well when they can be mounted on flat surfaces, however, if the surfaces are skewed, as is the case in most cases, several problems arise: for example, the passage of the guide elements in the rail is impossible, and locking devices do not function. Often the sliding and fixing devices of the prior art have complex locking and sliding mechanisms, which entails an increase in the cost of these devices.

A typical arrangement of sliding and locking devices for glass panels of a balcony is described in patent publication FI 101823. The publication shows the lower and upper guide element and glass panel 3, which can be rotated in a rotary unit around an axis passing through these elements. To fix the glass panel, the system includes a strip-like or disk-shaped fixing element 7 located above the upper guide element and fixed with its counter element. This type of locking element works well if the locking section can be positioned in relation to the counter element; but in the case when the upper rail must be installed, for example, in an inclined position, fixing can easily cause problems. This type of sliding and locking device also includes an upper guide element and a fixing portion held by a separate rail, which complicates the structure.

In prior art sliding and fixing devices for glass panels, the pivoting block of the upper rail includes a supporting protruding portion by which the pivoting rear end of the pane is supported by pivoting the panel until the fixing portions located in the rail can receive the fixing portions connected to the front end located in the pivoting unit of the glass panel. Now, depending on which point of the rotary unit each glass panel is to be attached, the location of the upper and lower guide elements of the sliding and fixing device for the glass panel located on the upper and lower edges of the panels must be adjusted. When the upper and lower guiding elements are not located at the ends of the glass panel, this leads, in turn, to the fact that after the installation is complete, it is not possible to freely choose the location of the rotatable block of the glass panel at the ends of the balcony, i.e. which side of the rotary unit is located on the balcony.

Disclosure of invention

The objective of the invention is to eliminate the above disadvantages of the prior art.

Thus, the main objective of the invention is to implement a balcony glazing system, equipped with a simple sliding and fixing device for the glass panels of the balcony, which operates under all conditions. An additional object of the invention is to implement a balcony glazing system in which it is possible to freely select the location of the rotatable block of the glass panel at the desired end of the balcony.

The main objective of the invention is achieved using the sliding and locking device described in claim 1, and the balcony glazing system described in claim 19.

More specifically, the invention relates to a sliding and locking device for fixing the position of a glass panel moving along the upper and lower rails at a predetermined angle relative to the upper rail. The upper rail comprises an upper side, a sole, an inner side and an outer side. At the upper edge of the glass panel, two upper guide elements are slidably mounted along the upper rail along the upper support profile, and two lower guide parts are slidably mounted along the lower rail at the lower edge of the glass panel. The glass panel is fixedly fixed between these lower and upper support profiles, so that at least the upper support profile extends from one end of the glass panel to the other end, and the panel can be rotated and fixed at an angle relative to the upper rail. Each upper guide element has the shape of a hemisphere and is made in the form of a fixing element by attaching it to the support profile fixed to the upper part of the glass panel by means of a rigid fastener that prevents mutual rotational movement between the support profile and the upper guide element, while the counter element of the specified upper guide element serving as the locking element is formed by a hole having the shape of a circle segment located on a shelf, so that the horizontal tal plane passing through said aperture, is located approximately at half the height of said upper guide member. The upper guide element of each pair of upper guide elements is attached to the support profile at the end of the specified profile and at the same time at the end of the upper edge of the glass panel.

In a preferred embodiment of the invention, the upper rail is provided with recesses that are located at the same point along the length of the upper rail as the fixing counter element located on a shelf attached to the side wall.

In accordance with the invention, the balcony glazing system comprises several upper and lower rails encircling the balcony, as well as glass panels movable along the upper and lower rails, each upper rail comprising an upper side, a sole, an inner side and an outer side, on the upper edge of the glass panels by means of a support profile are slidably attached along the upper rail two upper guide elements, and on the lower edge of the glass panel by means of a lower support profile Two lower guide parts are slidably slidable along the lower rail so that the glass panel is fixedly fixed between said lower support profile and the support profile, wherein at least the upper support profile extends from one end of the glass panel to the other end and can be rotated and fixed under angle relative to the upper rail. Each upper guide element has the shape of a hemisphere and is made as a fixing element by attaching it to the support profile fixed to the upper part of the glass panel by means of a rigid fastener that prevents mutual rotational movement between the support profile and the upper guide element, while the counter element of the specified upper guide element serving as a fixing element is formed by a hole having the shape of a circle segment located on a shelf, so that izontalnaya plane passing through said aperture, is located approximately at half the height of said upper guide member. The upper guide element of each pair of upper guide elements is attached to the support profile at the end of the specified profile and at the same time at the end of the upper edge of the glass panel.

The invention is based on the idea that the guiding elements sliding along the upper rail are arranged so that they can function simultaneously both as a supporting structure when sliding the glass panel along the rails and as fixation devices when rotating the glass panels in a swivel block at a given angle relative to the longitudinal direction of the upper and lower rails. This, in turn, becomes possible due to the fixed attachment of these upper guide elements to the upper support profile, as well as due to their hemispherical shape and the location of their fixing counter elements relative to the hemisphere, namely: the counter element is located on a horizontal plane passing through the geometric axis of the hemisphere.

Due to the fact that the fastening between the upper guide element and the upper support profile is fixed and rigid, the upper support profile and the upper guide element can be simultaneously fixed in the locking position; however, unlike prior art balcony glazing systems, no separate sliding and locking devices are required.

This type of hemispherical combined guide and fixing element is not sensitive to irregularities and distortion of the mounting surface of the rail structure; even if the side walls (outer and inner side), going down from the upper side of the upper rail, are not strictly vertical, but have a slight inclination relative to the vertical direction, this does not affect the functionality of the locking system, since the counter elements still remain in a horizontal plane passing through the geometric axis of the hemisphere; in the elements of the prior art that are used for fixing, the skew in the rail structure often leads to impaired functionality of the fixing elements.

Thanks to the use of a hemispherical combined sliding and guide element, it is possible to obtain an advantage in that nothing prevents the movement of the specified element along the upper rail, even if the rail is deviated from the vertical direction, in contrast to the case of fixing elements of the prior art, when the fixing elements are located separately from guiding elements and can hit the rail wall.

In a preferred embodiment, the upper rail is provided with a double sole and a bracket is directed from the support profile of the glass panel into the space between the upper sole and the lower sole of the double sole of the glass panel. In addition, a sliding support may be located between the lower sole and the double sole bracket. In this case, the bracket inserted in the double sole now supports the upper edge of the glass panel, which rotates in the rotary block K until the counter-element of the locking element located on the upper rail receives the locking element. Due to the use of this type of construction of the support profile of the upper rail and the glass panel connected to the combined fixing and upper guide element, in comparison with the prior art systems, it is possible to achieve an additional advantage, which consists in the absence of the need to attach an additional supporting protruding part to the upper rail in order to ensure horizontal the position of the glass panel during rotation of the glass in the rotary unit to the locking position. Now, the combined sliding and locking device of the present invention can be placed on the ends of all glass panels, which, in turn, provides free choice of placement of the rotary unit at the desired end of the balcony, i.e. The direction of rotation in the rotary unit can be selected before installation and even after installation. The term “end of the balcony” refers to that part of the balcony where the space of the balcony ends.

In prior art balcony glazing systems, it is necessary to make the upper guide elements rotating about a vertical axis, i.e. the fastening between the support profile and the upper guide element is not fixed, since the part of the upper guide elements located further backward with respect to the sliding direction is not located at the ends of the support profile. This method of attachment between the support profile and the upper guide element stems from the fact that in the known systems to maintain the position of the glass panel when the glass is rotated in the rotary unit, an additional protruding part is used.

Therefore, the advantages of the balcony glazing system of the present invention are based on two interrelated features: the connection between the upper guide element and the support profile is fixed, which, in turn, is due to the fact that all the upper guide elements are located at the ends of the glass panel. The upper guiding elements can be placed at the ends of the glass panel because there is no need in the construction of the invention to provide the upper rail with a separate supporting protruding part when the glass panels are rotated. The need for a protruding protruding part is eliminated due to the fact that in this invention the upper rail structure is changed by making the sole of the upper rail in the form of a double sole and by providing the support profile with a bracket with which the glass panel can be held on the specified double sole when the glass panel is rotated.

In addition, in another preferred embodiment of the invention, in the rotary block K, next to the counter element of each upper guide element at the same point along the length of the upper rail, a series of identical recesses are made in the sole of the upper rail, concentric with respect to the longitudinal geometric axis of the sole. By means of these recesses, the glass panel is not allowed to slide during its rotation in the longitudinal direction of the upper rail.

In another preferred embodiment, each lower guide member movable along the lower rail includes a horizontal rotating member. The guide part consists of two horizontal disks mounted on one axis, and these disks rotate in opposite directions while moving the guide part in the guide groove made in the lower rail. The guide chute is an element made in the lower rail parallel to the lower rail and bounded on one side by the sole of the lower rail, while the vertical sides of the specified guide chute form a wedge-shaped structure; its function is to rotate the guide parts in different directions while sliding the guide part along the guide chute. The guide piece can be biased toward the guide chute by a support arm connected to the guide piece; the force exerted by the spring is applied to the top of said support arm.

Preferably, the vertical sides of the guide chute are shaped so that the guide pieces coming into contact with them touch different vertical sides regardless of the inclination of the lower rail.

By using the design of the lower rail and the guide piece of this kind, the advantage is achieved that under all conditions the guide piece glides smoothly in the guide trough. Similarly, the connection between the guide part and the guide chute under all conditions is maintained without any gap, since the guide part is uniformly biased towards the guide chute by a predetermined force generated by the spring.

The elongated support arm passing through the box and pressing the guide piece also has some vertical tolerance. This means that in the balcony glazing system it is possible to obtain a certain tolerance for vertical draft.

Brief Description of the Drawings

The invention and its various advantages are described below with reference to the accompanying drawings.

Figure 1 is a perspective view of the balcony glazing system of the present invention, which shows the main parts of the sliding and fixing device of one glass panel placed in the upper and lower rails.

Figure 2 depicts the sliding and locking device corresponding to figure 1, if we consider it from the direction 1B in figure 1, without the upper and lower rails.

Figure 3 depicts a glass panel and its sliding and locking device corresponding to figure 1, if we consider it from direction II in figure 1.

Figure 4 is a perspective view showing the upper guide element of the sliding and fixing device of the glass panel of the first embodiment of the invention and the part of the glass panel attached to it, as well as the counter elements of the upper guide element located inside the upper rail.

Figure 5 depicts a support and fixation device, an upper guide element and a part of a glass panel attached to it, as well as anti-elements located inside the upper rail when viewed from direction IV in figure 4.

Fig.6 depicts the upper guide element of another variant of implementation when viewed from the same point as in Fig.5.

FIG. 7 depicts the upper guide element of the embodiment shown in FIG. 6 when viewed from the IVC direction of FIG. 6 when the upper guide element is slightly rotated with respect to the upper rail.

Fig.8 depicts the locking movement of the upper guide element relative to its counter element.

Fig. 9 is a schematic plan view showing, for comparison purposes, how glass panels in a prior art balcony glazing system are brought to a rotary unit located in a corner of the balcony.

Figure 10 depicts from the same point as in figure 9, how the glass panels in the balcony glazing system of the present invention are led to a rotary unit located in the corner of the balcony.

The upper row of images in Fig. 11 depicts recesses made in the sole of the upper rail, in the rotary block, close to the bottom of the lower rail, viewed in longitudinal section and directly from the side, in the direction of the outer wall of the upper rail, and the lower row of images depicts the upper guide elements in the same rotary unit viewed directly from above.

12, 13 and 14 depict a lower guide element located further rearward on the lower rail when viewed directly in the direction of the end of the glass element, where the lower rail is visible in cross section.

The implementation of the invention

In the following description, features of the invention illustrated by the accompanying drawings and structures shown in the drawings will be discussed.

Figures 1, 2 and 3 show one glass panel 5 in the balcony glazing system of the present invention, attached to the upper and lower guide elements 2, 3, i.e. to the device 1 sliding and fixing, viewed from different points of view. As can be seen from figures 1 and 2, there is one pair of both the upper guide elements 2 and the lower guide elements 3. The upper guide elements 2 are attached to the upper corners of the glass panel 5 by means of the upper support profile 4, and the guide parts 30 of the lower guide elements 3 are attached to the lower corners of a rectangular glass panel by means of a lower support profile 300.

The glass panel 5 is attached to the hemispherical upper guide elements 2 located above its upper edge and upper angle by means of a (upper) support profile 4, which, in turn, is attached to the upper part of the glass panel. On the same vertical line Q with the upper guide elements 2, guide parts 30 of the lower guide elements 3 are arranged. Each lower guide element 3 is formed by a lower support profile 300 attached to the lower part of the glass panel and serving all the lower guide elements, and attached to the specified lower support profile two guide parts 30. The guide parts 30 of the lower guide member 3 are located at a lower angle of the glass panel and can slide rotatably along neither it rail 8. As the upper support profile 4 and lower profile support 300 extend from one end of the glass panel 5 to the other end.

The upper rail 7 is connected to the surrounding fixing support 6, with which the system, in turn, is attached to the balcony structures (not illustrated). The glass panel 5 can rotate around the vertical axes Q1; Q2 drawn through the guide parts of the front and rear (upper) guide elements 2; 2 ', 2' 'located on the front and rear ends of the glass panel, and through the corresponding lower guide elements 3; 3 ', 3' 'located on the front and rear ends of the glass panel. With this design, an advantage is provided that the glass panel can rotate relative to any one of the vertical axes Q; Q1 or Q; Q2, so that you can freely choose the direction of rotation leading to the rotary unit K described below. The elongated upper rail 7 includes an upper side 73 and an outer and an inner side 76, 75 connected at right angles to the upper side, as well as a double a sole 70, on top of the upper sole of which the upper guide element 2 is supported. In its transverse profile, the upper rail 7 has a more or less rectangular shape, and between its inner side 75 and its sole 70 is provided about miles. Inside the space defined by the double sole 70, the inner side 75, the outer side 76 and the upper side 73 of the upper rail 7, there remains a closed sliding space T in which the upper guide element 2 is placed. The outer side 76 and the inner side 75 extend vertically and mutually are parallel. The double sole 70 and the upper side 73 extend horizontally and are mutually parallel.

4 and 5-7 show a hemispherical upper guide element, viewed from various points in more detail, where the specified guide element is located on the upper rail 7 in the sliding space T. The upper guide element 2 is attached to the glass panel 5 by means of a support profile 4. The upper guide element 2 serves both as the supporting structure for the glass panel 5 when sliding on the double sole 7 of the upper rail, and the locking element 2 when fixed with the counter element 20.

4, 5 and 6, the upper guide element 2 located inside the sliding space T of the upper rail 7 and the glass panel attached below it are shown in the initial position, i.e. in the position in which the upper guide elements 2 are usually located while sliding along the double sole 70 of the upper rail and in which they have not yet been rotated and fixed with their counter element 20 (hemispherical hole) located in the rotary block K of the upper rail, on the shelf 200 .

7, the upper guide element is shown in a position in which it is rotated into its locking position in the rotary unit.

In the initial position, the vertical flat surface 2a of the hemispherical upper guide element 2 is rotated in the direction of the vertical inner side 75 of the upper rail 7. The upper rail 7 in its upper part is connected to the fixing support 6, and under the upper side 73 of the upper rail 7 remains the regulating element 9, which used to adjust the angle between the fixing support 6 and the upper rail 7 and the vertical position of the upper rail 7.

Typically, the upper side 73 of the upper rail 7 and the horizontal portion of the fastening support 6 attached to the balcony are parallel. However, if the horizontal part of the fixing support 6, attached to the balcony, must be fixed in an unsuitable place or position, for example, due to irregularities in the ceiling of the balcony, the control element can be used to adjust the height of the upper side 73 of the upper rail 7, as well as its adjustment in the horizontal direction. The upper rail 7 is provided with a double sole 70, which is connected horizontally with the outer side 76, but not with the inner side 75, while this double sole is formed respectively from the upper sole 71 and the lower sole 72, which are parallel. Upper sole 71 is provided with a guide groove 70; 71; 71a in the longitudinal direction of the upper rail, and the rotary unit is provided with a series of successive cavities or recesses (see also FIG. 11). A guide groove 71a is formed by turning the free end of the horizontal upper sole 71 upward.

The hemispherical upper guide element 2 rests on its lower surface on the upper surface of the upper sole 71 in its guide groove 71a, so that the flat surface 2a of the upper guide element 2 is in the vertical position or even slightly deviated from the vertical position, for example, with a deviation of 5-10 degrees . The upper guide element 2 is attached to the upper part of the glass 5 by means of a support profile 4, which extends horizontally from one end of the glass panel 5 to the other end. In the vertical direction, the support profile 4 extends from the upper guide element, from the hole provided in the corner between the inner side 75 of the upper rail and the double sole 70, in the direction of the glass 5 located under the upper rail 8, and is attached to the specified glass by a rigid crimp connection. The hemispherical upper guide element 2 is attached to the support profile 4 under a narrow plate support arm 2b, connected directly to a flat surface 2a of the hemisphere. The support lever 2b is permanently fixed in the upward groove 4a formed by the upper end of the support profile 4. Due to the fixed, rigid mutual fixing of the upper guide element 2 and the support profile 4, the relative position of the upper guide element 2 and the glass 5 is rigidly attached to the support profile 4 , does not change during rotation of the upper guide element 2 (see also Figs. 7, 8 and 9) in the rotary unit, unlike the situation in the structures corresponding to the known solutions. Now, the guide element 2 of the upper guide can serve as a sliding element when moving along the upper rail, and as a locking element when the glass panel 5 is rotated in the rotary unit.

From the support profile 4 connecting the upper guide element 2 and the glass 5, an arm 41 protrudes into the space between the upper and lower soles 71, 72 of the double sole 70 of the upper rail 7. The bracket 41 extends from one end of the upper rail 7 to the other end on the same volume the same distance from the upper side 73 of the upper rail. The horizontal portion 72a of the lower sole 72 of the double sole 70 is provided with a pocket 72b into which the sliding plane 72 can be inserted. The sliding plane 72 c located in the pocket 72b facilitates the sliding of the support profile 4, as well as the sliding of the upper guide element 2 attached to it from above the lower sole 72 (see also FIGS. 6 and 7). The connection between the upper guide element 2 and the supporting profile 4 is located directly adjacent to the longitudinal vertical plane P drawn through the middle of the upper rail 7 and on the horizontal geometric axis L of the upper rail drawn at half the height of the hemisphere. Now, the flat surface 2a of the upper guide element 2 is in the initial position, located approximately on the specified vertical plane P, extending in the longitudinal direction of the upper rail, and the specified vertical plane is located half the width of the upper side 73, in the middle of the sliding space T. While the upper guide element 2 is in the initial position, its lower surface rests on the upper sole 71 of the double sole 70, on the crease 71a left between the horizontal section of the upper sole 71 and its free end turned upward, while this crease serves as the guide groove 71a of the upper guide element 2.

Hemispherical counter elements are located on a trihedral shelf 200, which tapers in the direction of its free peak and is mounted on the inner side 75 of the upper rail 7, while the specified free peak extends to the vicinity of the flat surface 2a of the guide element 2.

The locking counter element 20 of each upper guide element 2 is an opening 20 located on the structure of the shelf 200. The shelf is best seen in FIGS. 4 and 5-7. The holes located on the shelf are illustrated in FIGS. 8 and 11.

In a preferred embodiment of the invention, a series of recesses 25 are located on the fixing counter elements located on the shelf 200 on the upper sole 71 of the upper rail, by using a leveling element 250. This embodiment is illustrated in FIG. 11 and FIGS. 5-7.

The horizontal shelf 200 is located on a horizontal plane attached to the rotary block K of the inner side 75 of the vertical upper rail 7, i.e. at the point at which the glass panels 5 should rotate at the desired angle (usually about 90 degrees) with respect to the longitudinal direction of the upper rail. The rotary block shown in figure 5, is located on the other end of the upper rail 7 (see also Fig.9, 10). The lower edge of the shelf 200 is located on a horizontal plane that is held at half the height of the upper guide element 2. Thus, the shelf 200 is fixed on the inner side 75 at such a height that the horizontal lower edge of the shelf is located approximately half the height, i.e. the diameter of the hemispherical upper guide element 2 when viewed from the upper sole 71 of the upper rail 7. The holes 20 located on the shelf 200 are located next to each other, and at least as many as the glass panels included in the balcony glazing system. In their longitudinal profile, the holes 20 are round in shape and open in the direction opposite to the inner wall 75, in the direction of the upper guide element 2 located on the upper rail. The radius r of the holes is approximately equal to the radius of the hemispherical guide element 2. The free edge of the shelf 200 extends in the vicinity of the flat surface 2a of the hemispherical guide element 2.

The fixing of the guide element 2 with the counter element 20 is carried out as illustrated in Fig. 8. For simplicity, only the upper guide members 2 are shown in the drawing; 2'a, 2'b and a shelf 200, on which the counter elements 20 are located; 20 ', 20' ', 20' ''. In the situation shown in Fig. 8, the first glass panel on the right side is rotated 90 degrees from the inner wall 75 of the upper rail, where the specified inner wall 75 runs parallel to the shelf 200. A hemisphere 2'b connected to the first glass panel and used in as the upper guide element, rotated 90 degrees to fix it with the counter element 20; 20 'having a cross-sectional shape of a circle segment. Next to it is a hemisphere 2'a connected to a second glass panel, with the hemisphere 2'a just installed next to the 20 '' deflector; Now, by rotating the hemisphere 90 degrees counterclockwise, the glass panel attached to it is aligned parallel to the first glass panel.

Figure 10 depicts several glass panels 5, which are rotated, being adjacent, in the rotary block K in accordance with the method illustrated in Fig.6, 9 and 10, and which are located at an angle of 90 degrees relative to the longitudinal axis of the upper rail. Figure 10 also shows the placement of a pair of upper guide elements; both longitudinal ends of the supporting profiles 4 of each glass panel are provided with a guide element 2. On the inner side 75 of the upper rail, a hole is now made, not illustrated in the drawings, by removing the part in front of the rotary block to allow the guide element 2; 2 '', going further back, exit the top rail. The upper guide member 2 shown in FIGS. 6 and 7 is the front guide member 2; 2 ′ extending inside the upper rail of FIG. 10. From FIG. 7, it can be seen how the bracket 41 of the support profile 4, which rotates together with the guide element 2, all the time remains, at least partially, inside the sole, i.e. between the lower sole 72 and the upper sole 71, even if the rear end 4 ″ of the support profile 4 and at the same time the rear end of the glass panel 5 attached to the support profile are turned outward, i.e. in the direction of the inner wall 75 of the upper rail. Thanks to the double sole 70, which forms the pivot support for the bracket 41 of the support profile 4, the end of the glass panel slides along the rails 7, 8, supported by the guide parts of the upper guide elements 2 and lower guide elements 3, in other words, the end of the glass panel that goes further back , i.e. the rear end, it is not necessary to support the supporting protruding part, made separately on the upper rail 7, as is the case in the case of balcony glazing systems from the prior art, when the guide element 2; 2 '', attached by means of a support profile 4 at the upper edge of the end located at the farthest back point in the sliding direction of the glass panel 5, is rotated outward in the rotary block K. In a preferred embodiment, the explanation of which is described in more detail below with reference to FIG. 11 , the reliability of the rotation functionality of the glass panel 5 is improved by making hollows or recesses 25 on the upper sole 71 in the rotary block K by using a leveling element 250. The recesses 25 are not pos. olyayut glass panel 5 to move in the longitudinal direction of the upper rail 7 during the rotation operation. The design of the leveling element 250 in its main details is also visible in FIGS. 5, 6 and 7.

For comparison, balcony glazing systems known in the art are illustrated in FIG. 9. Here, only the sliding elements 21; 21 ', 21' 'extending along the upper rail of the glass panel, which should come into the rotary block K of the first, are attached at the ends of the upper supporting profile 4 of the glass panel, but in the remaining glass panels the sliding element 21' ', which is located further back in the direction movement, attached at a predetermined distance from the end (rear end) 4 '' of the support profile 4, which is located further behind in the direction of movement. The indicated distance depends on the place where the glass panel rotates in the rotary block K. The reason why the sliding element 21 "located further behind cannot be placed on the rear end 4" of the support profile, as is the case in the construction of the present invention , lies in the fact that in the known balcony glazing systems there is a supporting protruding part (not illustrated) located on the upper rail and protruding from it near the rotary unit K, and onto this supporting protruding part when the stack is rotated yannoy panel in the rotary block K relies end 4 'of the reference profile of the glass panel, which is located further behind in the conveying direction. This problem does not arise in the construction of the present invention, since the support profile 4 is held by the double sole 70 by the bracket 41 while the glass panel is rotated.

Figure 10 also demonstrates the advantage achieved by this type of construction of the balcony glazing systems 10 of the present invention in comparison with the known balcony glazing systems (Fig. 9). If the fence V is located so that it extends outside the upper rails 7 in the immediate vicinity of them, the glass panel 5 provided with guide elements of the present invention can be easily passed past the angle between the upper rails 7; 7 'and 7; 7 '', since the upper guiding elements 2 are located at the ends of the supporting profile 4 attached to the glass panels, and the upper guiding elements 2 always extend inside the upper rail 7. In systems of the prior art, only both guiding elements of the glass panel that should come in the rotary block K of the first is placed at the ends of the support profile connected to the glass panels, and the upper guide element of the other glass panels, going further back in the sliding direction, is mounted in the support profile e glass panel more centrally, so that in this case, those ends of the glass panels, which are arranged on the back, can bump into the fence in the angle V between the two upper rails.

In the balcony glazing system 10 of the invention, both the upper pairs of guide elements and the lower pairs of guide elements of all glass panels can be placed at opposite ends of each glass panel (FIG. 10). Now the upper and lower rails, found in the corner at an angle of 90 degrees, can be cut with a bevel angle of 45 degrees.

When the glass panels 5 of the balcony glazing system 10 move along the upper and lower rails supported by the upper guide elements 2 and the guide parts of the lower guide elements 3, the upper guide elements 2 can move in the corner between the upper rails directly from the upper sole of the first upper rail to the upper sole of the second top rail. Typically, the guide element 2 extends inside the rail in the initial position (see also Figs. 4-7), i.e. its flat surface 2a is parallel to the longitudinal axis of the upper rail, however, in the corner and after the corner, the front guide element at some point goes so that its flat surface is at an angle relative to the longitudinal axis of the upper rail. Thus, it is not required that the upper guide element can rotate relative to its vertical axis P and the supporting profile, as is the case in balcony glazing systems known in the art, and the fastening between the upper guide element 2 and the supporting profile 4 can be performed with permanent fixation.

In prior art balcony glazing systems, the upper guide elements must be rotatable about a vertical axis, i.e. the fastening between the support profile and the upper guide element is not fixed, since part of the upper guide elements 21; 21 '', which are located further back in the direction of movement, is not located at the ends of the supporting profile 4. Thus, the upper guide element 21, which is made with the possibility of rotation relative to the supporting profile, cannot simultaneously function both as a sliding device and as a fixing device unlike the upper guide element 2 of the present invention.

As already indicated, when the glass panel is rotated as illustrated in FIG. 10, it is not required that the end of the glass panel 5, which extends further from the rear relative to the direction of movement, be supported in any way in the rotary block K. This is due to so that the bracket 41 of the support profile 4 is of sufficient length to extend so deep into the space between the lower and upper soles of the double sole 70 that the bracket 41 is held for a sufficiently long time during rotational movement, at least at least one part of it, in the space between the lower and upper soles of the double sole 70, thereby forming together with them the support of rotation. At a certain point in the rotational movement, the front guide member 2; The 2 ″ begins to slide into the locking counter element 20, so that the end of the 5 ″ glass panel extending further from the rear does not need to be held separately.

When using the balcony glazing system 10 of the present invention, the glass panels of the balcony can be assembled on either side of the balcony, since the upper guiding elements 2: 2 ', 2' 'of all glass panels are located at the same point of the supporting profile 4 attached to the glass panel 5, those. at the ends 4 'and 4' 'of the supporting profile 4. Thus, the structures of all the upper guide elements 2, as well as their location on the supporting profile 4 of the glass panel are mutually identical. In this case, the lower guide elements 3 are also mutually identical and are at the same point of the guide elements.

11 and 5-7 illustrate another preferred embodiment of the invention, comprising a leveling element 250 mounted in a rotary unit on the upper rail. In the rotary block of the upper rail next to the counter element of each upper guide element at the same point along the length of the upper rail 7 on the upper sole 70; 71 of the upper rail 7 made a series of identical recesses 25; 25 ', 25' ', 25' '', concentric with respect to the longitudinal geometric axis of the sole, by using a leveling element 250, which can also be seen in FIGS. 5-7.

Figures 5-7 show the location of the alignment element 250 on top of the upper sole 71 of the upper rail 7. The alignment element 250 is a separate plastic alignment piece mounted in the pivot block at the top of the upper sole 71 of the upper rail, and comprises a series of recesses 25 made in the sliding portion 27 located at the top of the upper sole 71, and the connecting part 26, which is connected at right angles to the section 27 of the sliding leveling element. The connecting part 26 is parallel to the outer side 76 of the upper rail and is attached to it using a suitable connecting node.

11 depicts a leveling element 250 located at the top of the upper rail in the rotary block and provided with three recesses 25 in the sliding section 27. In the upper row of images in Fig. 11, the upper rail is shown directly from the side, and in the lower row of images it is shown directly from the top. In the upper row of images, the outer side of the upper rail is visible from the level of the upper sole; here, the specified outer side of the upper rail remains behind the connecting part 26 of the outer side attached at the top of the leveling element. In the bottom row of the drawings, said connecting piece 26 is visible at the top of the image. Two recesses 25; 25 'and 25; 25 '' from among the recesses 25, an upper guide element 2 is attached, while one of the recesses 25; 25 '' 'remains free.

Thus, the two upper guide elements 2; 2'a and 2; 2'b shown in the drawings are placed in two left recesses 25 'and 25' ', while the right recesses 25; 25 '' 'remain free. Upper guide element 2; 2'a brought into the recess 25; 25 ', located farthest on the left side, is in a position in which the glass panel has just been brought into the rotary unit, i.e. glass panel and upper guide element 2; 2'a not yet turned into a recess 25; 25 '. Therefore, the specified upper guide element 2'a has not yet been rotated into its fixing counter-element, and this means that its flat surface 2a; 2aa is aligned in the longitudinal direction of the upper rail 7. With regard to the second upper guide element 2; 2'b located in the central recess 25 '', it is already rotated 90 degrees to its locking position, and this means that the glass panel has been rotated 90 degrees with respect to the longitudinal direction of the upper rail, so that it is now rotated block K in the position illustrated in FIG. 10. Flat surface 2a; 2ab of said upper guide member 2; 2'b is located at an angle of 90 degrees relative to the longitudinal direction of the upper rail 7.

The purpose of the recesses 25 is to align the upper guide element 2; 2 'with respect to its counter element so that the user cannot even accidentally rotate the glass panel anywhere else except precisely to the counter element. When the upper guide element 2; 2 'is installed in the recess 25, said recess 25 prevents the upper guide element from moving in the longitudinal direction of the upper rail 7, thereby preventing the glass panel from moving in the longitudinal direction of the upper rail 7, so that the upper guide element 2; 2 'rotates and is easily fixed in its counter element. Similarly, since the recess 25 does not allow the upper guide element 2; 2a to move in the longitudinal direction of the upper rail 7 during rotation, the edge of the flat surface 2a of the upper guide element 2 does not come into contact with the edge of the counter element when turning.

12, 13 and 14 illustrate in more detail the lower guide element 3 of the glass panel of the sliding and fixing device used in the balcony glazing system. The design of the lower guide member 3 was more generally shown above in FIGS. 1 and 2 when describing the drawings.

12 illustrates a situation in which the rear lower guide member 3; 3 '', located on the lower rail 8, is in the initial position, or the position in which the specified lower guide element is located when the glass panel is held by the upper and lower guide elements located on the upper and lower rails, respectively.

13, in turn, illustrates a situation in which the glass panel 5 in the rotary unit has just begun rotation.

Fig. 14 illustrates a situation in which the glass panel and its lower guide element have already partially rotated in the rotary unit.

12-14 show a cross section of a lower rail 8 and a rear lower guide member 3; 3 ″, located on the lower rail, which is connected to the lower support profile 300. The specified rear lower guide element 3 ″ can be rotated together with the glass panel 5 in the rotary unit (see also figure 10). The lower guide element 3 contains the following elements, which will be described in more detail below: the support arm 32, a vertical box 301 provided with a compression spring that surrounds the support arm, and a guide piece 30 connected to the specified support arm.

The glass panel 5 at its lower end is attached to the lower support profile 300, which is directed downward from the glass panel and extends from one end of the glass panel 5 to the other end. Through the vertical box 301, which is made in the lower support profile 300 and is located next to the glass panel, in the upper and lower direction there is a support lever 32 of the lower guide element 3; 3 ', while the support arm protrudes in its lower position (Fig. 12) a certain distance below the lower edge of the box 301 provided in the lower support profile 300. A prestressed compression spring (not shown) is placed inside the box, which biases the support arm 32 downward, in the direction of the guide groove 80, and simultaneously in the direction of the sole of the lower rail 8. The lower end 32a of the support arm 32 is in the form of a horizontal bracket 32a, which is directed exactly in the direction of the outer side, and the horizontal guide th part 30 is associated with the specified bracket 32a. The guide piece 30 is formed of two parallel, concentrically connected and superimposed disks: the upper guide part 30a and the lower guide part 30b. The support lever 32 aligns the connection point of the guide parts 30 to one vertical level with the plane of the glass panel 5.

The lower rail 8 is formed of a vertical outer wall 86 and a vertical inner wall 85, as well as a horizontal sole 81, which connects the outer and inner walls. As can be seen in FIGS. 12-14, the inner wall 85 and the outer wall 86 have approximately the same height. The upper edge of the inner wall 85 is folded inward so as to form a horizontal bracket 85a. The bracket 85a extends from one end of the inner wall to the other end, except that a hole is placed in the rotary unit so that the lower guide piece 30 can be lifted from the guide groove (hole of the bracket 85a: see also Fig. 13). From the sole 81 of the lower rail, a predominantly vertical intermediate wall 8 rises; 88. Two supports 81b are attached to the sole 81 of the lower rail, having a transverse profile in the form of two inverted letters L, with short dashes of letters facing each other.

A guide groove 80 is formed in the space defined by the inner wall 88, the sole 81 and the inner wall 85. The vertical walls defining the guide groove 80, i.e. the inner side 88a of the wall of the intermediate wall 88 and the outer side 85b of the wall of the inner wall 85 are mutually shaped so that when moving both the lower guide part 30b of the guide part 30 and the upper guide part 30a touch only one of these sides 85a and 88a and that the guide parts 30a and 30b concerned different sides. In the embodiment of the invention illustrated in FIGS. 12-14, the lower guide piece 30b, when placed in the guide chute, touches the inner side 88a of the intermediate wall 88, and the upper guide piece touches the inner side 85b of the inner wall. When the guide piece 30 moves along the guide groove 80, the upper guide piece 30a and the lower guide piece 30b rotate in opposite directions, on the one hand, due to friction between the lower guide piece 30b and side 88a, and, on the other hand, due to friction between the upper guide piece 30a and side 85b. In the embodiment of FIGS. 12-14, the contact of the equal guide pieces 30a, 30b with the different sides 88a, 85b of the guide chute when moving the guide piece 30 along the specified guide chute is effected by the wedge-shaped design of the guide chute, as well as by the compression spring, which biases the support arm 32 and then the guide piece 30 down. In the embodiment illustrated in the drawing, the wedge-shaped design of the guide groove 80 is implemented so that from a location approximately below the mid-height of the inner side 88; 88a of the inner wall, side 88a is curved in the direction of the inner wall 85, while above the middle of the indicated height, the side wall 88a is curved in the direction of the outer side 86. Thus, the transverse profile of the side 88a resembles the letter S with a gentle slope. Accordingly, the inner side 85b of the inner wall 85 is shaped so that from a location approximately above the mid-height, the surface of the inner side 85b is straight or slightly curved towards the outer wall 88, while below the middle, the surface of the inner wall 85b is very curved to the side from the outer wall 86.

12 shows a situation in which the guide piece 30 of the rear guide member 3; 3 'moves in the wedge-shaped guide groove 80, or, otherwise, the guide piece 30 is in the initial position in the specified guide groove 80. The support arm 32 is in its lower position, pressing the upper guide piece 30a of the guide piece 30 towards the inner side of the intermediate wall 88 and the lower guide piece 30b in the direction of the inner side of the inner wall 85, due to the action of a compression spring located in the box 301. The guide piece 30 is sandwiched between the vertical walls 85 and 88 of the direction the gutter groove 80. Thus, the compression spring ensures that the parts 30a, 30b of the guiding part 30 are always tightly pressed without any clearance to the vertical sides 88a and 85b of the guiding groove 80 so that even with strong wind the guiding parts 30 of the glass panels in the balcony glazing system could not move in the guide groove 80. This prevents the usual noise and rattling of the glass panels of balconies in windy weather. The wedge-shaped design of the above-described guide groove 80 ensures that the lower guide part 30b and the upper guide part of the guide portion 30 always rotate in opposite directions despite being located on the same axis of rotation, thereby providing an additional advantage, namely that the guide piece 30, under any conditions, moves in the guide chute 80 smoothly and evenly. In addition, the vertical walls 88a and 85b of the guide chute are also shaped as described above, so that the upper guide part 30a and the lower guide part 30b are always in contact with different sides of the vertical wall, even if the sole 81 of the lower rail 8 deviates from the horizontal direction .

FIG. 13, in turn, illustrates a situation in which the glass panel 5 is ready for rotation in the rotary unit (see also FIG. 10 and its description). The guide piece 30 rises from the guide chute 80 through an opening provided in the bracket 85a at the upper edge of the inner wall 85. The support arm 32 supporting the guide piece 30 is in its upper position.

Fig. 14 illustrates a situation in which the front end of the glass panel 5, simultaneously with the rear guide element 3 ″ attached to the front end of the lower supporting profile of the glass panel, is rotated inward through an opening made in the inner wall 85 of the rotary unit. A pair of horizontal discs forming a guide piece 30 of the rear guide member 3 ', i.e. the lower guide piece 30b and the upper guide piece 30a are integrally transferred over the edge of the inner wall 85 of the lower rail 8, while the rotational movement can be continued so that the glass panel 5 rotates 90 degrees relative to the lower rail (see also FIG. 10 ) On Fig glass panel is open inside the balcony. On the corresponding front lower guide element in the rotary unit, there is no hole in the inner wall 85, which means that it cannot exit the guide channel 80.

The elongated support arm 32 passing through the box 301 has some tolerance for movement in the vertical direction. If the supporting structures above the upper rail 7 in the balcony glazing system or the upper rail 7 itself protrudes downward so that the upper rail 7 slides in the direction of the lower rail 8, the distance between the lower end 32a of the support arm and the lower edge of the glass panel 5 can be adjusted to upper and lower positions of the support arm. By using the above-described construction of the support arm 32 and the compression spring biasing said arm down, it is possible to achieve the advantage that the support arm 32 cannot touch the lower rail and the guide piece 30 continues to slide smoothly in the guide groove 80. Thus, in the system glazing of the balcony a certain tolerance for vertical draft is achieved.

In the foregoing description of the invention, only a few embodiments of the sliding and fixing device 1 of the present invention have been described, as well as several embodiments of the balcony glazing systems provided with this device, and it will be apparent to those skilled in the art that the invention can be implemented in many other ways within the scope of the invention, which follows from the attached claims.

For example, the adjusting element 9 may be similarly located between the fixing support and the upper rail, as well as under the upper side 73 of the upper rail 7. The shelf 200 may also have a flat shape.

Reference List

one Sliding and locking device 2 Upper guide element 2a Flat surface of the upper guide element 2b Support arm of the upper guide element 2'a, 2'b The front ends of the upper guide elements,   connected to separate glass panels 2 ', 2' ' Front and rear ends of the upper guide   element (in accordance with the invention) 21 ', 21' ' Front and rear ends of the upper guide   element (not the present invention) 25 ', 25' ', 25' '' Top rail recesses twenty Holding element   top guide 20 ', 20' ', 20' ' Locking Elements   top guide 200 Shelf for counter elements 250 Alignment element 25 Leveling recess, cavity 26 Alignment fitting 27 Leveling Slide 3 Lower guide element thirty Guide piece 30a Lower guide piece 30b Upper guide piece 32 Support arm 300 Lower support profile 301 Box provided in lower support profile four (Upper) support profile 4 ', 4' ' Front and rear end of the support profile 41 Support bracket 5 Glass panel, glass 5 ', 5' ' Front and rear edge of the glass panel 6 Fastening support 7, 7 ', 7' ' Top rail 70 Double outsole 71 Upper sole double soles 72 Bottom sole double soles 71a Upper sole guide groove 72a Horizontal section of the bottom sole 72b Bottom sole pocket 72c Glide plane 73 Upper side 75 Inner side 76 Outside 8 Lower rail 80 Guide rail in the lower rail 81 Bottom rail 85 Inner wall of the lower rail 86 The outer wall of the lower rail 88 Lower rail intermediate wall 9 Control element 10 Balcony glazing system K Swivel block L Geometric axis of the upper rail P Vertical plane Q1, Q2 Vertical axis r Locking element radius T Slip space V Fencing

Claims (31)

1. The device (1) sliding and fixing to fix the position of the glass panel (5), moved along the upper and lower rails, at a given angle relative to the upper rail (7), and the specified upper rail (7) has an upper side (73), the sole (70), the inner side (75) and the outer side (76), while on the upper edge of the glass panel by means of the upper support profile (4) two upper guide elements (2; 2 'and 2, 2 ”), and on the lower edge of the glass panel through the lower of the second supporting profile (300), two lower guide elements (3; 3 'and 3; 3 ”) are slidably attached along the lower rail (8), so that the glass panel (5) is fixedly fixed between the indicated lower supporting profile (300) and the upper supporting profile (4), at least the upper supporting profile (4) extends from one end of the glass panel (5) to the other end with the possibility of rotation and fixing at an angle relative to the upper rail (7), characterized in that each upper guide element (2; 2 ', 2; 2 ”) has the shape of a hemisphere and is made in the form of a fixing element by attaching it to the upper support profile (4), mounted on the upper part of the glass panel (5) by means of a rigid mount, which prevents mutual rotational movement of the upper support profile (4) and the upper guide element (2), while the counter element (20) of the specified upper guide element (2) serving as the fixing element is formed by a hole (20) in the form of a circle segment located on the shelf (200), so that it is horizontal the plane passing through the hole is approximately half the height of the specified upper guide element (2), with each upper guide element (2 ', 2 ”) of each pair of upper guide elements (2) attached to the upper support profile (4) on the end of the support profile and, at the same time, at the end of the upper edge of the glass panel. 2. The device according to claim 1, characterized in that the sole of the upper rail (7) is made as a double sole containing the upper sole (71) and the lower sole (72), and from the upper supporting profile (4) of the glass panel into the space between the upper and the lower soles (71, 72) of the double sole (70) is directed to the bracket (41), which serves as a support of rotation, and the upper rail (7) is made with the possibility of attachment through its upper side (73), both directly and indirectly, to a planar element, for example, to the ceiling of a balcony. 3. The device according to claim 2, characterized in that both the upper supporting profile (4) and the bracket (41) attached to the supporting profile extend from one end of the glass panel (5) to the other end, the bracket (41) the supporting profile (4) of the glass panel, inserted between the upper and lower soles (71, 72) of the double sole (70), serves as a supporting structure when the upper guide elements (2; 2 ', 2 ”) slide along the upper rail (7) along the bottom sole (71) of the double sole (70). 4. The device according to claim 2 or 3, characterized in that on top of the bottom sole (72) of the double sole there is a sliding plane (72c), which facilitates the sliding of the bracket (41) of the upper support profile, as well as the sliding of the upper guide element (2), attached to the upper support profile (4). 5. The device according to claim 2, characterized in that the upper rail (7) in the transverse profile is a rectangle and has a flat upper side (73), a double sole (70), the outer side (76) and the inner side (75), which together form a closed structure, inside which a space (T) is left for sliding. 6. The device according to claim 5, characterized in that the counter element (20) of the upper guide element (2) is located on the shelf (200) attached to the rotary block (K) on the inner side (75) of the upper rail, and when the upper guide is located element (2) in the initial position in the rotary block of the shelf (200) is placed between a plane drawn through a flat surface (2a) of the upper guide element (2), and the inner side (75) of the upper rail. 7. The device according to claim 6, characterized in that the shelf (200) protrudes horizontally from the inner wall (75) of the upper rail into the upper rail directly in the vicinity of the flat surface (2a) of the hemispherical guide element (2). 8. The device according to claim 6 or 7, characterized in that in the rotary block K, next to the counter element (20) of each upper guide element (2) at the same point along the length of the upper rail (7), on the sole (70) of the upper rail (7) made a series of identical recesses (25), concentric with respect to the longitudinal geometric axis of the sole. 9. The device according to claim 8, characterized in that the recesses (25) in the rotary block (K) are made by using a leveling element (250) located on the upper rail, and said leveling element forms a portion placed on top of the upper sole (71) the upper rail, and contains a series of recesses (25) made in the section (27) of the slide located on top of the upper sole (71), as well as the connecting part (26) located parallel to the outer side (76) of the rail and attached to it using the connecting node, and with edinitelnaya piece (26) attached to the sliding portion (27) at an angle. 10. The device according to claim 1, characterized in that each lower guide element (3) moved along the lower rail (8) includes a horizontal rotating part (30) containing a lower guide part (30b) and an upper a guide piece (32a) mounted on one axis, said guide pieces (30a, 30b) rotating in opposite directions while moving the guide piece (30) along the guide groove (80) made in the lower rail (8). 11. The device according to claim 10, characterized in that the guide groove (80) is an element located parallel to the lower rail on the lower rail and bounded on one side by the sole (81) of the lower rail, the vertical sides (85, 88) of the specified groove (80) form a wedge-shaped structure for rotating the guide parts (30a, 30b) in opposite directions while sliding the guide part (30) along the guide groove (80). 12. The device according to claim 11, characterized in that the vertical sides (85, 88) of the guide trough are shaped so that the guide parts (30a, 30b) that come into contact with them touch different vertical sides, regardless of the angle of the sole ( 81) of the lower rail (8) relative to the horizontal direction. 13. The device according to claim 10, characterized in that the guide part (30) is attached to the lower end of the elongated support arm (32) with the possibility of displacement of the guide part (30) by means of the support arm (32) in the direction of the bottom of the guide groove (80). 14. The device according to item 13, wherein the upper part of the support arm (32) is connected to a box (301) made next to the lower support profile (300) of the glass panel, while a spring element is placed inside the box, which pushes down both the support arm (32) and the guide piece (30) attached to its lower end. 15. The device according to 14, characterized in that the distance between the lower end (32a) of the support arm (32) and the lower edge of the glass panel can be adjusted both in the lower position and in the upper position of the support arm. 16. The device according to claim 2, characterized in that on the upper sole (71) of the upper rail (7) in the longitudinal direction of the upper rail there is a guide groove (71a), which includes the lower end of the upper guide element (2), while the guide the groove (71a) is preferably a crease made on a flat upper sole (71). 17. The device according to p. 16, characterized in that the guide groove (71a) is preferably located in the transverse profile of the upper rail at half its width (L). 18. The device according to claim 1, characterized in that the upper rail (7) through its upper side (73) is attached to a fixing support (6), which can be attached to a planar element, for example to the ceiling of the balcony, and directly below the upper side (73) of the upper rail (7), a control element (9) is provided for adjusting the vertical position of the upper rail and / or the distance between the planar element and the fixing support (6). 19. Balcony glazing system (10), comprising upper and lower rails (7, 8) encircling the balcony, as well as glass panels (5) moving along the upper and lower rails, with each upper rail (7) having an upper side ( 73), a sole (70), an inner side (75) and an outer side (76), while on the upper edge of the glass panel by means of a support profile (4) two upper guide elements are slidable along the upper rail (7) (2; 2 'and 2, 2 ”), and on the lower edge of the glass panel through the lower support profile (30 0) two lower guide elements (3; 3 'and 3; 3 ”) are slidably attached along the lower rail (8), so that the glass panel (5) is fixedly fixed between the indicated lower support profile (300) and the upper support profile ( 4), at least the upper supporting profile (4) extends from one end of the glass panel (5) to the other end with the possibility of rotation and fixation at an angle relative to the upper rail (7), characterized in that each upper guide element (2 ; 2 ', 2; 2 ”) has the shape of a hemisphere and is made in the form of a fixing element by attaching it to the upper support profile (4), mounted on the upper part of the glass panel (5) by means of a rigid mount, which prevents mutual rotational movement of the upper support profile (4) and the upper guide element (2), while the counter element (20) of the specified upper guide element (2) serving as the fixing element is formed by a hole (20) in the form of a circle segment located on the shelf (200), so that it is horizontal a plane passing through said hole is approximately half the height of said upper guide element (2), with each upper guide element (2 ', 2 ”) of each pair of upper guide elements (2) attached to the upper support profile (4) at the end support profile and, at the same time, at the end of the upper edge of the glass panel. 20. The system according to claim 19, characterized in that to each glass panel (5) using the upper supporting profile (4) and the guide part are attached two pairs of guide elements consisting of upper and lower guide elements (2, 3), said pairs of guide elements are located at the ends of each glass panel. 21. The system according to claim 20, characterized in that the upper guide element (2) and the lower guide element (3) of each glass panel (5) are located on the same axis (Q), and each upper guide element (2) is attached to the upper a supporting profile (4) connected to the glass panel (5), so that the flat surface (2a) of the specified guide element in the initial position is turned towards the inner side (75) of the upper rail (7), and each upper guide element (2) the initial position is supported by a guide groove (71a), filled in the double sole (70) of the upper rail, wherein the guide groove (71a) is preferably located at half the width (L) of the transverse profile of the upper rail. 22. The system according to any one of paragraphs.19-21, characterized in that it includes a rotary unit (K) of a glass panel, which is configured to install at any point on the upper rail (7) by placing shelves (200) in the rotary unit, equipped with fixing antielements (20), and by creating a hole on the inner side (75) of the upper rail (7), allowing the rear upper guide element (2; 2 ”) of each glass panel (5) to be removed from the upper rail (7) through the hole . 23. The system according to any one of claims 19-21, characterized in that from the upper supporting profile (4) of the glass panel into the space between the upper and lower soles (71, 72) of the double sole (70) is directed bracket (41), serving in as the supporting structure for the glass panel (5) during sliding of the specified glass panel supported by the upper guide element (2) next to and above the upper rail (7), the upper supporting profile (4) and the bracket (41) extending from one end of the glass panel (5) to the other end, and between the bottom sole (72) double oh sole and said bracket (41) is arranged plane (72) sliding that facilitates sliding of the support profile, and attached thereto an upper guiding member (2). 24. The system according to claim 19, characterized in that the bracket (41) of the upper support profile (4) and the double sole (70) of the upper rail (7) together form a rotation support at the rear end of the glass panel (5), such that when turning a guide element (2) connected to the rear end of the specified glass panel by means of the upper support profile (4) in the direction from the upper rail (7) in the rotary unit (K) during the specified rotational movement, the bracket (4) remains between the lower and upper soles ( 71, 72) double soles (70). 25. The system according to claim 19, characterized in that the bracket (41) of the upper supporting profile (4) is configured to function together with a double sole (7) as a pivot support during rotational movement, until the front guide element (2 ; 2 ') will not begin to be held in its fixing counter-element (20). 26. The system according to claim 19, characterized in that in the rotary block K, next to the counter element (20) of each upper guide element (2) at the same point along the length of the upper rail (7), on the sole (70) of the upper rail ( 7) a number of identical recesses (25) are made, concentric with respect to the longitudinal geometric axis of the sole. 27. The system according to p. 26, characterized in that the recesses (25) formed in the upper rail are made in the rotary block (K) by using a leveling element (250) located on top of the upper sole (71) of the upper rail and containing a number of recesses (25) made in the sliding section (27) located on top of the upper sole (71), as well as the connecting part (26) located parallel to the outer side (76) of the rail and attached to it by means of a suitable connecting node, the connecting part ( 26) is connected to slip point (27) at an angle. 28. The system according to claim 19, characterized in that each lower guide element (3) moved along the lower rail (8) includes a horizontal rotating part (30) containing a lower guide part (30b) and an upper a guide piece (32a) mounted on one axis, said guide pieces (30a, 30b) rotating in opposite directions while moving the guide piece (30) in the guide groove (80) made in the lower rail (8). 29. The system according to p. 28, characterized in that the guide groove (80) is an element located parallel to the lower rail on the lower rail and bounded on one side by the sole (81) of the lower rail, the vertical sides (85, 88) of the specified gutter (80) form a wedge-shaped structure for rotating the guide parts (30a, 30b) in opposite directions while sliding the guide part (30) along the guide groove (80). 30. The system according to p. 28 or 29, characterized in that the inner wall (85) of the lower rail (8) is provided in the rotary unit with a hole through which the rear lower guide element (3; 3 ”) passes while the glass panel is rotated (5 ) by a certain angle relative to the lower rail (8). 31. The system according to p. 30, characterized in that in the rotary unit (K) on the front lower guide element (3; 3 ") in the inner wall (85) of the lower rail (8) there is no hole.

Images