CZ308078B6 - Safety heating glazing - Google Patents

Abstract

Safety heating glazing contains at least two flat glass substrates, of which at least one is hardened and, at the same time, on the inside has an electronically conductive heating mesh. The flat glass substrates, which are separated from each other by a chamber filled with a noble gas with low conductance temperature, are inserted into a common frame. All the flat glass substrates are formed of 3 to 8 mm thick floated soda-lime glass and containing 70 to 72.5 wt. SiO, 13 to 14 % by weight NaO, 9 to 10 % by weight CaO, 4 to 5 % by weight MgO, 0.60 to 0.75 % by weight AlO, 0.10 to 0.14 % by weight KO, 0.25 to 0.27 % by weight SOand up to 1 % by weight of other additives. The electrically conductive heating mesh is of SnO2: F and is 5 to 100 nm thick and a visible area of 79 to 84%, an ultraviolet radiation of 84 to 86%, an infrared radiation of 57 to 59%. It is interconnected convex polygons so that the area current density is constant throughout the electrically conductive heating mesh and is fed by the first heating electrode and the second heating electrode. The first heating electrode is connected by a conductor through a relay switch to a phase conductor of an adjustable thermostat connected to the power supply. The second heating electrode is connected by the conductor to a neutral conductor to the electricity supply, which is connected through a relay coil by a conductor through a safety electrode with the phase conductor, led through the chamber in the frame through a magnetic contact connected to the electric distribution network by the conductor to the phase conductor of the regulated thermostat, which is connected through the conductor to a thermal sensor at the edge of the glass substrate and the relay contact is connected to the digital input of the control system through a control unit in the switchboard of the electric current, transmitting and evaluating accidental impulses to verify the closure of the heating circuit. The adjacent flat glass substrates are 9 to 30 mm apart, depending on the width of the chamber, filled with a low thermal conductivity noble gas, stated by a plastic spacer with a rectangular cross-section with bevelled corners at the base. The rectangular base and the adjacent chamfers have a vapour barrier aluminium coating up to one half of its length adjacent the base. The plastic distance frame is filled with a molecular synthetic crystalline aluminosilicate sieve with a 0.29 to 0.31 nm diameter three-dimensional pore system and fixed along the vertical sides with a permanently flexible non-conductive polyisobutylene sealant and on the side of the base and bevel with a two-component polysulfide fixing compound. The noble gas is selected from argon, krypton.

Description

Title of the invention:

Heating safety glazing

Annotation:

The safety glazing comprises at least two flat glass substrates, of which at least one is hardened and at the same time is provided with an electrically conductive heating network on the inside. The flat glass substrates, which are separated from each other by a chamber filled with a noble gas of low thermal conductivity, are embedded in a common frame. All flat glass substrates are formed of floated soda-lime glass having a thickness of 3 to 8 mm and containing 70 to 72.5% by weight. S1O2, 13 to 14 wt.%. Na2O, 9-10 wt.%. CaO, 4 to 5 wt.%. MgO, 0.60 to 0.75% by weight. Al 2 O 3, 0.10 to 0.14% by weight. K 2 O, 0.25 to 0.27% by weight. SO3 and up to 1% by weight of other additives. The electrically conductive heating network is of SnO2: F and has a thickness of 5 to 100 nm, a visible transmittance of 79 to 84%, an ultraviolet transmittance of 84 to 86%, an infrared reflectance of 57 to 59%. It is in the form of interconnected convex polygons such that the area current density is constant throughout the electrically conductive heating network and is fed by the first heating electrode and the second heating electrode. The first heating electrode is connected by a conductor through a relay switch to a phase conductor of an adjustable thermostat connected to the power supply. The second heating electrode is connected by a conductor to the neutral conductor of the power supply, which is connected via a relay coil by a conductor through a safety electrode to a phase conductor, guided by a chamber in the frame via a magnetic contact connected to the power distribution network. connected by conductor a temperature sensor located on the edge of the glass substrate and the relay contact is connected to the digital input of the control system via the control unit in the electrical switchboard, sending and evaluating random pulses to verify the heating circuit closed. Adjacent flat glass substrates are spaced 9 to 30 mm apart, depending on the width of the chamber, filled with a rare gas of low thermal conductivity, delimited by a plastic spacer with a rectangular cross-section with bevelled corners at the base. The rectangular base and adjacent chamfers are provided with a vapor barrier aluminum coating up to one half of its length adjacent the base. The plastic spacer is filled with a molecular sieve based on synthetic crystalline aluminosilicate with a three-dimensional pore system with a diameter of 0.29 to 0.31 nm and fixed along the vertical sides with a permanently flexible non-conductive polyisobutylene based sealant and base with two component . The rare gas is selected from argon, krypton.

Claims (7)

A heating security glazing comprising at least two flat glass substrates (1, 7), at least one of which is provided with an electrically conductive heating layer fed by heating electrodes separated from one another by a chamber (9) filled with noble gas of low thermal conductivity and embedded in a common frame ( D), characterized in that all flat glass substrates (1,7) are formed of float soda-lime glass of 3 to 8 mm thickness, containing 70 to 72.5% by weight. S1O2, 13-14 wt.%. Na 2 O, 9 to 10% by weight. CaO, 4 to 5 wt.%. MgO, 0.60 to 0.75% by weight. Al 2 O 3, 0.10 to 0.14% by weight. K 2 O, 0.25 to 0.27% by weight. The SO3 and up to 1% by weight of the other additives and at least one of the outer flat glass substrates (1, 7) are hardened and at the same time provided with an electrically conductive heating network (6) having a thickness of 5 to 100 nm, made of SnCKF. having a visible transmittance of 79-84%, an ultraviolet transmittance of 84-86%, an infrared reflectance of 57-59%, in the form of interconnected convex polygons such that the area current density is constant throughout the electrically conductive heating network (6) ), powered by a first heating electrode (2) and a second heating electrode (4), wherein the first heating electrode (2) is connected by a conductor (a) via a switch (NO) of a relay (5) to a phase conductor (L) of an adjustable thermostat R connected the second heating electrode (4) is connected by conductor (b) to the neutral conductor (N) of the power supply. power, which is connected via coil (C) of relay (5) by wire (c) via safety electrode (3) to phase conductor (L), led through the chamber in the frame via magnetic contact (M) connected to the electric grid by conductor (d) to the phase conductor (L) of the controllable thermostat (R), to which the temperature sensor (T) located at the edge of the glass substrate (1) is connected to the conductor (e) and the contact (NC) of relay (5) is connected to digital input (DIx) ) the control system, by means of a control unit in the electrical switchboard, emitting and evaluating random pulses to verify the heating circuit closed and the adjacent flat glass substrates are at a distance of 9 to 30 mm relative to each other according to the width of the chamber (9); delimited by a plastic spacer (8) with a rectangular cross-section with bevelled corners, where the base (V) of the rectangle and the adjacent bevel (Z) are u provided with a vapor barrier aluminum coating (H) up to one half of its length adjacent to the base (V), the plastic spacer (8) is filled with a molecular sieve based on synthetic crystalline aluminosilicate with a three-dimensional pore system of 0.29 to 0.31 nm diameter; fixed along the vertical sides (X) by a permanently resilient non-conductive polyisobutylene-based sealant (11) and at the base (V) and bevel (Z) side with a two-component polysulfide-based fixing sealant (10) and that the noble gas is selected from argon, krypton . A safety glazing unit according to claim 1, characterized in that the conductors (a), (b), (c), (d) are routed together through the disconnectable connector (K). The safety glazing unit of claim 1 or 2, wherein the convex polygons are selected from the group consisting of triangles, quadrilaterals and hexagons. The fire safety glazing unit according to claims 1 to 3, characterized in that the flat glass substrates (1, 7, 14) are three and the intermediate substrate (14) is provided with a reflective layer (12) from the interior side. Heating security glazing unit according to one of Claims 1 to 4, characterized in that the external exterior glass substrate (7) is provided on the inside with a heating network (6). Heating security glazing unit according to Claims 1 to 4, characterized in that the outer exterior glass substrate (7) is provided with a reflective layer (12) on the inside. A safety glazing unit according to claims 1 to 6, characterized in that the polygons have a width (m) and a width (n) of the side of 2.4 to 6.5 mm and a length (k) and a length (1) of the side of 11. , 41 to 51 mm.