RU2035577C1 - Window, double glass pane and device for fixing double glazing - Google Patents

Abstract

FIELD: civil engineering; glazing. SUBSTANCE: multiple glass unit has profiled glass flanges formed by protruding glass edge extending beyond the opposite side or glass strip glued the glass. The double glass pane is fixable in an enveloping casing directly or by means of racks and may have also pentagonal form. Device for fixing double glass pane covers the whole double glass pane surface, is rigid and engages both of the glasses, receives and distributes stresses arising due to bearing reaction forces. Device has the form of a grille or has some more complicated pattern. Windows are manufactured with pentagonal leaves and triangular or tetragonal air vent narrowing downwards to prevent from penetrating the house through the air vent. EFFECT: simplified window construction and operation reliable protection capability. 12 cl, 5 dwg

Description

 The invention relates to the construction, namely, to the construction of windows and glued glass units, and can be used in the manufacture of windows, doors, etc.

A window is known including a binding consisting of wooden and aluminum parts, glazing of binding cells with double-glazed windows and gap seals between them. The wooden part of the binding is located on the outside of the window, and the aluminum on the inside. The sealant between the double-glazed windows and the aluminum part of the binding is made of heat-conducting material [1]
A disadvantage of the known window is the insufficient rigidity of the binding.

A prototype is a double-glazed unit made of two rows of parallel-arranged glasses having a U-shaped contour frame between the glasses with a profiled protrusion formed on the continuation of the side wall of the frame, in the perpendicular direction relative to its shelf, equipped with a flange with an elastic gasket fixed to it, interacting with the surface of the framing box. A sealant is placed in the formed gap between the profiled protrusion and the elastic gasket [2]
The well-known double-glazed window is structurally complex and, therefore, time-consuming.

 A device for fixing double glazing in a double-glazed window, comprising spacer elements located between the glasses and in contact with their inner surface (application UK No. 1529021, CL E 06 B 3/66).

 The disadvantage of this device is that the spacer elements transfer the load to the glass only along its perimeter, for example, supporting forces, as a result of which the connection between the spacer elements and the glass at the place of application of force is possible.

 The prototype is a device for fixing double glazing in a double-glazed window, including spacer elements in the form of elastic rods located between the glasses both around the perimeter of the double-glazed window and along its area, attached to one glass and in contact with another (A.S. USSR N 1032158, C. E 06 B 3/66).

 The disadvantage of this device is that the second glass accepts the load from the spacer elements only around the perimeter, as a result of which the glasses are unevenly loaded, and the elastic spacer elements are not able to transfer significant loads to the glass without deformation.

 Known window unit containing a window box, glazed outer and inner bindings with window leaves (A.S. USSR N 1164391, class E 06 B 5/20).

 The disadvantages of this window unit are the presence of glazing bindings and the possibility of unauthorized access to the room through the window.

 A window is taken as a prototype, including a box, frames fixed therein for a rotary shutter and a window leaf, between which there is an axis of the window leaf mounted horizontally, and gaskets (AS USSR N 1333760, class E 06 B 3/00).

 The disadvantages of the known window is the presence of a frame for the pivoting sash and the window and the possibility of unauthorized access to the room through the window.

 Currently, a window block is used to fill the window opening, containing a box and a binding, the cells of which are glazed with sheet glass or double-glazed windows. Binding occupies a substantial area in the window opening, which reduces the amount of light entering the room. The binding consists of rotatable or non-rotatable casement frames. The main function of the frames is carrier. The frame takes the load from the glazing and its own weight and transfers them to the box. The dead weight of the frame may be greater than the weight of the glazing, and the bulk of the frame material is used to absorb the loads due to dead weight. Frames during operation are deformed, change their own dimensions due to moisture differences, if they are hygroscopic, rot or rust from the presence of condensation on the inner surface of the glass and atmospheric moisture outside. Blind window fillings are also used, in which there are no frames, and the glazing is mounted on the box, but they are not always applicable, since the window also has a ventilation function, in which case it is difficult to care for the outer surface of the window. To ventilate the room in the window eliminate the window. The arrangement of the window leaves forced to install additional binding elements, which increases material and labor costs, makes the sash heavier. During the performance of its main function, the window can be used for unauthorized access to the room. In an existing window, fans, air conditioners, communications can be installed, there may be windows that require screening of part of the window for their placement, which is desirable to produce at the lowest cost.

 The double-glazed window includes two rows of glazing made of parallel arranged glasses, a spacer frame, a profiled protrusion and a framing box. The invention is directed to the exclusion of the frame from the sash. Glued double-glazed window contains two rows of glazing and a contour spacer frame. Profiled protrusions that ensure overlapping joints between the sash and the framing box and located on the sides of the sash are formed by the edges of the glasses protruding beyond the opposite side of the glass packet. The protrusions can be made on top of the glazing in the form of glued profiled glass strips. The double-glazed window can be installed in the box and fixed in it as a fixed or rotary casement, in the second case it is connected to the box by means of curtains attached to the spacer frame. If it is necessary to arrange the window, the double-glazed window is pentagonal with one cut-off angle, and the window is triangular. The double-glazed window transfers the load from its own weight to the box through the curtains. The double-glazed window is a rigid spatial structure, capable of absorbing forces from internal and external loads and transferring them to the curtains or to the box due to the joint work of the glasses and the contour contour frame, rigidly connected at the contact points. The exclusion from the sash of the frame also determines the absence of drawbacks inherent in the sash of the frame: size fluctuations due to moisture differences, deformation in the interfaces of the elements, rotting and corrosion, accumulation of dust, dirt and moisture in the relief and the joints with glazing. This simplifies the maintenance of the valves during operation, does not require the cost of a waterproof coating, since glass perceives the main environmental influences, is a resistant and hygienic material.

 A sufficient sign in all cases during the implementation of the invention is the presence of at least one profiled glass protrusion protruding from the opposite side of the glass packet on an adhesive double-glazed window. Particular cases of implementing the invention are: the presence of a protrusion formed by a protruding edge of the glass pane protruding from the opposite side of the glass pane, a protruding profiled glass strip glued to the glass, as well as connecting the glass pane with the box with or without curtains and making the pane angular.

 One of the goals is the strengthening of a double-glazed unit containing spacer elements located between the glasses and in contact with their inner surface both around the perimeter of the double-glazed unit and in its area, and giving it additional design capabilities. The fastening of the double-glazed unit to the box by means of curtains causes the appearance of stresses in the spacer frame, the glue joint connecting the spacer frame and glass, and glass. These critical stresses can lead to the destruction of the adhesive joint, frame or glass at the points of attachment of the curtains. To reduce stress, it is necessary to increase the area of the adhesive connection of the spacer frame with glass. In addition, an increase in the load-bearing capacity of a double-glazed unit is possible by reducing the deflection of the glass under the influence of critical stresses. The problem is solved by placing between the glasses over the entire area of the double-glazed window hard spacers attached to both glasses. The spacers are arranged in such a way as to disperse as much as possible the main stresses arising in the glass packet. At the same time, the spacer elements can perform a security or design function. So, the spacer elements may form a lattice or pattern. The location of the spacer elements in the form of a lattice is most advantageous in terms of achieving the smallest deflections of glass on the surfaces of the glass packet. With a decrease in deflections, the bearing capacity of glasses absorbing the main load increases.

 A sufficient sign in all cases is the presence of at least one rigid spacer element located not around the perimeter of the glass packet and rigidly attached to both glasses. Particular cases of the invention are the location of the spacer elements: for the distribution of stresses from the supporting forces, in the form of a lattice and in the form of a pattern.

 The invention is aimed at reducing the cost of arranging a window in a window containing a framing box, glazing, a sash, including a window, and a window, while giving it a security function from unauthorized access to the room. The window is made of a triangular shape, tapering downward, and is a sash as part of the frame or separate from the main sash along the line cutting off the upper corner of the sash, connected to the sash or framing box. This form of the window allows you to reduce the number of window elements and the interface nodes of the window elements to three, the number of frame elements due to the use of the window, to one directly in contact with the inclined side of the window. Reducing the consumption of material and labor for the manufacture of window leaves, sash elements, mates of these elements, as well as increasing the light transmittance of the window by removing excess binding elements are positive results of this decision. To provide the possibility of opening the window in the traditional way, by turning around the axis of the side curtains, the window can be made quadrangular tapering downward. The triangular or quadrangular shape of the window, tapering downwards, makes it difficult to penetrate through the window due to the fact that when the body rests on an inclined frame element or pentagonal leaf, it will shift downward under its own weight and jam in the lower corner of the window opening. There are no signs sufficient in all cases. Particular cases of the invention are: the use of a pentagonal leaf with one cut corner, the presence of a triangular or quadrangular window, tapering downward.

 In FIG. 1 shows a double-glazed window consisting of a window with a triangular window; in FIG. 2 section AA in figure 1; figure 3 section BB in figure 1; figure 4 section bb in figure 1; figure 5 a fragment of a window with a quadrangular window, tapering down.

 The double-glazed window 1 contains two rows of glazing 2 and 3, a contour spacer frame 4, glass protrusions 5 and 6 overlapping the joints 7 between the sash 8 and the framing box 9. The protrusion 5 is formed by the glass 3 protruding beyond the dimensions of the opposite side. The protrusion 6 is formed by glued onto the glass 2 a profiled glass strip 10 protruding beyond the dimensions of the opposite side of the double-glazed window 1. The double-glazed window 1 is connected to the framing box 9 by means of curtains 11, attached to the frame 4 by screws 12, and has a pentagonal shape.

 Double-glazed window 1 works as follows.

 The double-glazed window 1 mounted on the box 9 is rotated on the curtains 11 and closes the inner opening of the box 9. The profiled protrusions 5 overlap the joints 7 on the three sides of the double-glazed window 1 of one side of the window 13, and the protrusions 6 on the two sides of the other side of the window 13, namely, on the sides of the curtains 9 and the porch of the window 14.

 The device for fixing double glazing 2 and 3 in the double-glazed window 1 contains spacer elements 4 located along the perimeter of the double-glazed window 1. Spacer elements 15 of the device for fixing, located over the area of the double-glazed window 1, are made of a metal profile 15 and connected to the glass 2 and 3 by an adhesive joint 16 The nodes of the lattice 17 or the convergence of the elements of the patterns 18, made of spacer elements 15, are located in the immediate vicinity of the mounting points of the curtains 11.

 A device for fixing double glazing 2 and 3 in the double-glazed window 1 works as follows.

 When a double-glazed unit 1 is hinged, in the places where the curtains are mounted on the contour spacer frame 4, supporting forces begin to act, creating stresses in it, which it transfers to glass 2 and 3 by means of an adhesive joint 16. In this case, tensile or compressive stresses arise in glasses 2 and 3, propagating over the entire area of glasses 2 and 3 and gradually decreasing with distance from the attachment points of the curtains 11. The stress isolines will represent concentric curves diverging from the places where the supporting reactions are applied. When the rigid spacer elements 15 are located across the isolines and their connection with glasses 2 and 3 is rigid, a part of the stresses arising in the glass in more stressed areas due to the stiffness of the adhesive joint 16 will be absorbed by the spacer elements 15 and transferred to less loaded sections of the glasses 2 and 3 located along the length of the spacer element 15, thus the redistribution of critical forces arising in glasses 2 and 3 will occur. When the spacers 15 are located across the isolines, the best redistribution of ylium arising in the glasses 2 and 3, provided with an adhesive compound 16 concentration in the areas of maximum stress. In the case of the location of the spacer elements 15 in the form of a lattice 17 with rigid nodes of intersection of the elements coming from the places of concentration of unlike stresses, the main load in its plane will be the lattice 17. Spacer elements made in the form of patterns (fragment a in figure 1), diversify the appearance of the window and redistribute the forces arising in glasses 2 and 3.

 The window unit 13 contains a pentagonal sash 8, a triangular window 14, made similarly to a double-glazed window 1 and mounted on a framing box 9 by means of curtains 19. To form a triangular opening in the corner closed by a window 14, the double-glazed window 1 is made pentagonal with one cut corner. In the case of installing the curtains 20 on the window 21 to allow opening around the O-O axis, the window 21 is made quadrangular, tapering downward. The size of the bottom side of the window opening provides a pinch of the human body. The portion of the opening not closed by the window 21 is closed by the insert 22.

 The opening of the window, tapering downward, formed on one side by a pentagonal sash 8, and on the other sides by a box 9, in the case of performing the security function works as follows. When trying to penetrate through a vent window, the penetrator is forced to take an uncomfortable inclined position. At the same time, his arm and leg, turned upwards, are turned off from work, he is not able to use them and is forced to act with one hand and foot. He will be forced to lean his body on the inclined element 23 of the double-glazed window 1. Under the influence of its own gravity, the body will move to the lower corner of the opening, where it will jam. As a result of a long struggle with the resulting jamming, the penetrating weakens and hangs in the window, where it can be neutralized without much effort.

Claims (12)

 1. A double-glazed window comprising two rows of parallel-located glasses, a contoured frame of a U-shaped section with a profiled protrusion and a framing box, characterized in that the profiled protrusion is made of glass.  2. The double-glazed window according to claim 1, characterized in that the profiled protrusion is formed by the edge of the glass protruding beyond the profiled side of the double-glazed window.  3. The double-glazed window according to claim 1, characterized in that the profiled protrusion is formed by a profiled strip glued to the glass.  4. The double-glazed window according to claim 1, characterized in that it is connected to the framing box.  5. The double-glazed window according to claim 1, characterized in that it is connected to the framing box through the curtains mounted on the contour frame.  6. Double-glazed window according to paragraphs. 1 and 5, characterized in that it is made pentagonal.  7. A device for fixing double glazing in a double-glazed window, including spacer elements located between the glasses and in contact with their inner surface over the entire area of the double-glazed window, characterized in that the spacer elements are rigid and attached to both sides.  8. The device according to claim 7, characterized in that the spacer elements are arranged to form a pattern.  9. The device according to claim 7, characterized in that the spacer elements are located with the formation of the lattice.  10. A window containing a framing box, at least one row of glazing, a sash and a window leaf, characterized in that the sash is made pentagonal.  11. The window of claim 10, wherein the window leaf is triangular, tapering downward.  12. The window of claim 10, characterized in that the window is made of a quadrangular, tapering downward.

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