DE3125597A1 - FIRE PROTECTION INSULATION GLAZING - Google Patents

Description

JENAer GLASWERK
SCHOTT & GEN.

Hattenbergstrasse 10
6500 Mainz

description

As a result of the energy shortage, insulating glazing is already required by law for exterior glazing in many countries. Thus, the requirement for fire protection insulating glazing also arises automatically, because in some outdoor areas the installation of fire protection glazing is essential. If currently It must also be assumed that not all of the exterior glazing is made of ßrandschutz insulating glazing, even in high-rise buildings will exist, so can the fire-resistant insulating glazing but are useful in stairwell glazing, Glazing next to stairwells, in corner areas of buildings where two fire compartments meet, or in high-rise buildings different usage.

«Β

. ::: "ϊ: Σ J *: -: ο ι ο cc α π

The aim of the present invention is an insulating glazing that one Fire test according to DIN 4102, according to the standard temperature curve (Fig. 1), for at least 30 minutes, preferably 60 and 90 minutes, withstands. Among the technical requirements for normal double glazing are to be provided, there is also the requirement for fire protection. The claimed fire protection insulating glazing should therefore meet the requirements of G 30 glazing or G 60 or G 90 glazing fulfill.

There are essentially three groups of G single glazing known, which differ significantly in their mode of action.

The first group is wired glass. Resists without special precautions the fire test only takes 30 minutes (G 30), as it bursts after a few seconds and begins to flow after 30 minutes. Should the wired glass withstand the fire test longer, then holes must be drilled in the edge of the glass and the glass must be fastened to the frame with pins. The soft glass then hangs in the wire mesh, which in turn hangs on the pins. For limited pane sizes, fire times of 90 min (G 90).

The second group of G single glazing are glasses with one low product of thermal expansion and modulus of elasticity and a high softening temperature ( > 800 ° C), which are additionally thermally prestressed. These glasses survive the heating process without breaking. Due to the high softening temperature of the glass, these glasses achieve service lives of G 90 and G 120. A glass in this group is available on the market under the trade name PYRAN (Glaswerke SCHOTT).

The third group of G single glazing includes transparent glass ceramics (ROBAX ₅ Glaswerke SCHOTT). These glass-ceramics contain a high proportion of high-quartz mixed crystals, which give the glass-ceramic an extremely low thermal expansion of. $ - 1 * 10 "K between 0 ° C and 500 ° C. Due to the low thermal expansion, these glasses are resistant to those occurring during the heating process Completely insensitive to temperature differences. The high crystalline phase content gives these glasses a high temperature resistance. These glasses can withstand the fire test for 240 minutes without deforming.

Multiple glazing is also available under the name CONTROFLAMM G (Vereinigte Glaswerke) known, but withstand the fire for a maximum of 60 minutes (G 60). They consist of thermally pre-stressed commercially available Window glass panes with a special perforated frame system.

In contrast, the insulating glazing according to the invention is sufficient for both technical requirements of normal insulating glazing as well as the fire protection requirements for G-glazing according to DIN 4102.

According to the invention, the insulating glazing is made up of at least two panes ₅ of which at least one pane is a fire protection pane with a product of linear thermal expansion (oO and elasticity

2
modulus (E) of less than 0 ₉ 4.N / (mm K) and having a softening temperature (Ew) vont 800 ° C.

According to the invention, the insulating glazing is constructed or possessed in this way such devices that the tensile stresses caused by the temperature differences between the center of the pane and the edge of the pane and as a result of internal pressure. " are always smaller than the total strength at least a fire protection pane.

* «St

-8th-

The insulating glass panes, which are supposed to withstand the fire for more than 60 minutes, are separated by spacers which consist of a material that ^{does not melt below 700 °} C. and which preferably contain a reinforcement in the two upper corners.

The panes are bonded using an organic adhesive that complies with DIN 4102, i.e. it is flame-retardant and / or is self-extinguishing.

The differs from the previously known G-glazing claimed G 90 double glazing by being next to the fire protection properties fulfills the properties of normal insulating glazing. From the previously known G-multiple glazing distinguishes itself through the simpler frame structure. For the stressed G insulating glazing no special perforated frame is required.

To explain the invention, the problem of fire protection insulating glazing is briefly discussed below.

As with single glazing, fire protection insulating glazing must also A distinction is made between two phases in the fire test, the heating phase and the fire phase. During the heating phase, temperature differences between the hot ones also arise in the panes of the insulating glazing V- ^ disc centers and the covered disc edges. These

Differences in temperature can cause tensile stresses Δ T in the panes and lead to the destruction of the panes.

In contrast to single glazing, insulating glazing occurs additional stresses © due to internal pressure.

As with single glazing, fire protection insulating glazing must also care must be taken that no opening occurs during the fire test, i.e. at least a fire protection pane remains in the frame and allows the room to be closed off.

Compared to normal insulating glass production, there is an additional problem that the permanently elastic putties used, which are commonly used today, must be flame retardant and / or self-extinguishing.

According to the invention, the fire protection pane must be designed in such a way that it shatters neither as a result of the temperature difference between the center of the pane and the edge of the pane nor as a result of the internal pressure during the heating process. It has been found that fire protection panes with a product of linear thermal expansion CA. and modulus of elasticity E of £ 0.40 N / mm K), a compressive prestress ") in the glass surface of
Preamble ₂

- '- ε \ fi $ 0 - 30) Γ N / mm J and a softening temperature

A temperature of ^ 800 ⁰ C survive the heating process if the pressure pre-tension is reduced in the first 15 minutes of the course of the fire »

The temperature differences measured on double insulating glazing according to the invention, which occur between the center of the pane and the edge of the pane in the heating phase of the fire test, are plotted against the heating time in FIG. 2. The measurements were made on insulating glazing made of two 6 mm PYRAN fire protection panes measuring 1 m χ 1 m with a glass spacing of 12 mm. The insulating compound had a valve made of Wood's metal for pressure equalization and was built into a steel frame with a 25 mm high glass retaining bead. The glass cover was 20 mm. The temperature difference ^ T on the side facing the fire passed its maximum value of about 320 K after about 10 minutes. On the side facing ^away from the fire, it reached a maximum value of 180 ° C. after 15 minutes.

The pressure equalization in the first 15 minutes after the start of the Fire tests can be carried out by means of a temperature valve, a pressure valve or by appropriate selection or treatment of the remaining Insulating glass panes are made.

For toughened glasses with a product of thermal expansion o £. and Young's modulus E of

0.09 <ot χ E <0.4 [N / (mm ² K) J

the load caused by the internal pressure _{should not exceed <5 id} ^ 20 N / mm if possible. For glasses with e * - * E <0.09 N / (mm ² K), the load due to the internal pressure should be ^. 40 N / mm.

For pressure compensation valves that respond to temperature, the response temperatures are plotted in Fig. 3 as a function of the length of the smallest edge for both types of glass (<$ ^^ 20 N / mm ² and C> _iD ^ 40 N / mm ² ). A valve made of Wood's metal, for example, can be used as the temperature valve. However, any other valve that responds to a temperature below the line drawn can be used according to the invention, for example org. Materials or solutions with other thermal effects, such as a bimetal effect. The temperature curves depend somewhat on the thickness of the glass panes.

For pressure compensation valves that respond to pressure, FIG. 4 the response pressures are plotted against the shortest edge length. Here, too, the curves are recorded, which lead to an additional loading

2
load on the panes of 20 or 40 N / mm due to the internal pressure.

«- 'In the case of panes with ^ In the shortest edge length, the response pressure changes barely. The pressure valves are better suited for small double glazing than for big ones. With large double glazing, very sensitive pressure valves are installed. This effect can be explained by the fact that large panes bulge out much more than small slices.

According to the invention, the insulating glazing can also be constructed so that the pressure equalization takes place through the premature bursting of the remaining panes, while the fire protection pane remains undamaged.

The remaining panes must burst so early that the tensile stresses in the fire protection glass _s caused by the temperature difference (^ * j) between the edge of the pane and the center of the pane and the internal pressure ( 6 ■ *) are always less than their total strength (6 _BZ )

⁰ BZ ^{yd +} ^

= Total strength = flexural strength N / mm = stress due to temperature difference between pane center and pane edge & * Q - stress due to internal pressure.

The overall strength of a glass is made up of the basic strength <$ g and aer pressure bias dv _orsD> if the disc is biased. The basic strength also includes the edge strength. In order for the remaining panes to shatter in front of the fire protection pane, the following condition must be met

^ G * ^d Vorsp / ^d AT " ^Ö iD>BSG> ^ G ^{+ (j} Vors _P r ^ T" 3oWl .Glas-

slices.

The critical case arises when the fire protection pane is facing the fire. _N fire duration, the tensile stress - in this case arises in the Fire Protection glass by temperature difference of 15 _mi

$ χ E ₁ x 320 (fire protection glass),

and in the glass pane on the side facing away from the fire the tensile stress

^ ^{x E} 2 ^{x 180} ί ^rest1 glass panes).

For panes of the same thickness, d. _{Q is the} same in both slices and therefore falls out of the equation.

An insulating composite according to the invention can thus consist of a fire protection pane according to the definition given above and an equally thick or thinner pane of glass with oC XE > / 0.6 N / (mm K) (eg window glass) without an additional valve. With the same dimensions and the same internal pressure, thin panes are always more heavily stressed by the internal pressure than thicker panes. If the remaining panes are thinner than the fire protection glass, they shatter much more quickly than this.

Should the remaining glass panes be used for safety reasons made of safety glass, i.e. made of glasses with a compressive tension of

2
100 N / mm exist, then these panes must either contain a defined damage that reduces their strength to the strength of a normal pane, or they must be more than a millimeter thinner than the fire protection glass.

In addition to the heating process, the duration of the fire plays an important role in the choice of the structure of the insulating glazing and its installation in a frame. It has been found that insulating glazing with a service life of 60 and 90 minutes can also be produced if sufficient contact pressure is maintained for the duration of the fire test. The contact pressure is maintained during the entire fire test if the spacer between the insulating glass panes is made of a material that does not melt below 700 ° C. A spacer made of steel profile tube has proven to be particularly advantageous. Since the fire protection panes made of glass with 0.09 ^ oc x E 0.4 N / (mm ² K) and Ew 800 ° C already begin to soften before 90 minutes have been reached, they tend to pull the spacer down . For example, a steel profile tube must have a sufficient wall thickness according to the dimensions of the pane and / or contain a reinforcement in the corner connection that prevents the spacer from sinking. The corner reinforcement can be

For example, from a somewhat longer »solid steel welded around the corner exist, which is inserted into the steel hollow profile. Of the Solid steel should protrude further into the hollow profile, the larger it is the pulley diameters are. The corner reinforcement also prevents excessive downward bulging of the spacer due to this thermal expansion.

As in accordance with DIN 4102 for fire-resistant glazing the side facing away from the fire must not develop flames over long periods of time »the organic adhesive and the sealing lips must be used of the frame are made of self-extinguishing materials.

The fire resistance period of 60 minutes is compared with the one according to the invention Insulating glazing according to DIN 4102 is only achieved if the insulating glazing is installed in a frame that extends over the entire length Maintains a specified contact pressure during the more than 60-minute fire test.

The glass inset in the frame should be 20 t 3 mm for the G 60 and G 90 fire protection insulating glazing.

The following exemplary embodiments are intended to provide further explanation contribute to the invention.

». .-31 2-§

- 14 -

example 1

In Fig. 5 is a fire protection insulating glazing, installed in a Steel frame, shown. The fire protection insulating glazing is made from a thermally pre-stressed fire protection pane 1 of 6 mm thickness and a non-pre-stressed window glass pane of 4 mm thickness. the Fire protection pane 1 consists of a borosilicate glass with

c ^ XE = 0.20 N / (mm K), a _{compressive prestress} of <5 ^{VorsD = 40} N / mm

and a softening temperature of Ew = 815 ° C. The spacer consists of a steel profile tube that is filled with molecular sieve and is slotted to the interior. Through a water vapor diffusion barrier and a permanently elastic, flame retardant, self-extinguishing one Mass 5, the insulating glazing is glued and the interior is sealed to the outside •.

The fire protection insulating glazing is made by pressing with screws or tilting strips held in the fold during the fire test and thus-a Prevents slipping out in the event of fire.

Example 2

6 shows the section of fire protection insulating glazing with a 6 mm fire protection pane 7 and a 6 mm window pane 8. The fire protection pane 7 consists of a transparent glass ceramic with a thermal expansion of <J- = 0.1 x 10 "K. The Ew of this Glass ceramics cannot be exactly determined due to the presence of the crystals, but it is above 1000 ° C.

Example 3

Fig. 7 shows a fire protection insulating glazing with two 6 mm thick fire protection panes 1 and a pressure valve 9 with membrane 10. The fire protection panes are the fire protection panes described in Example 1. The dimensions of the discs are 400 mm χ 1200 mm. The pressure membrane is designed in such a way that it is at a

2
Internal pressure of 0.01 N / mm tears.

Example 4

8 shows fire protection insulating glazing consisting of a 6 mm thick, thermally pre-stressed fire protection _{pane 1, corresponding to Example I 9,} and a 6 mm thick, thermally pre-stressed window pane. The pressure equalization in the event of a fire takes place through a valve 12, which responds to temperature. A small aluminum tube is closed with a low-melting Wood's metal 13.

Example 5

In Fig. 9, a spacer made of steel profile tube is shown with a corner reinforcement made of solid steel. The corner reinforcement is particularly important for the upper spacer, but also in the lower corners he brings a _s albeit small, improvement.

Claims (1)

.0125597 597 JENA GLASSWORK
SCHOTT & GEN.
Hattenbergstrasse 10 6500 Mainz Fire protection insulating glazing Claims ; 1. Component with multi-pane insulating glazing, at which at least one of the glass panes is a fire protection pane that has passed a fire test according to DIN 4102 the unit temperature curve, withstands for at least 30 minutes, and spacers between the discs are provided, characterized by the following features: 1 "1 - the fire protection pane consists of a glass or a glass ceramic, for which the product of linear thermal expansion oCiind modulus of elasticity E ^ (OCXE) <0.4 N / (mm ² K), and β O BV <Μ mm * <♦ β * -2- 1.2 - its softening temperature Ew _> 800 ⁰ C; 1.3 - the fire protection pane points in the surface layer a compressive prestress (5> ((X * E X 180 - 30) N / mm; 1.4 - the component is constructed in such a way that it is in addition to the Fire protection pane has a pane of equal thickness or thinner made of a glass with the product oC XE> 0.6 N / (mm K), and / or _____ i_ 1.5 - the component contains suitable means in the first 15 minutes after the start of the fire test, pressure equalization between the interior of the component and its surroundings to reach. 2ο insulating glazing according to claim 1, characterized in that 1.3.1 - the fire protection pane in the surface layer has a compressive prestress ο it (OCyEX 320 - 30) N / mm. 3. insulating glazing according to claim 1 or 2, characterized in that that 1.1.1 - the fire protection pane made of one glass with the product 2
OC * E = 0.2 N / (mm K), as well as 1.2.1 - Ew = 815 ° C, and that 1.3.1.1. - the pre-print generated by thermal pre-tensioning 2
tension <? 2 34 N / mm. 4. insulating glazing according to claim 1, characterized in that 1.1.2 - the fire protection pane made of a transparent high-quartz mixed crystal containing glass ceramic with the product CC XE <0.09 N / mm ² K) and with 1,2.2 - "Ew"> 100O ⁰ C exists. 5 ο insulating glazing according to one of claims 1 to 3, characterized marked that 1o5o1 - these means for pressure equalization consist of valves, either to a rise in temperature or a rise in pressure in the air gap between the insulating glass panes speak to. 6. insulating glazing according to claim 4, characterized in that in thermally toughened fire protection glasses with 0.09 <_ oCX E <0.4 N / (mm ² K), the valves are set so that they open at an internal pressure in the Disc a tension of <& 0 N / ^ iu
caused. 7ο insulating glazing according to claim A, characterized in that that in the case of fire protection glass with © CxE <0.09 N / (mm K), the valves are set so that they open at an internal pressure that causes a tension of <ή · 0 H / Ύη fti in the pane. 8 ο insulating glazing according to one of claims 1 to 3, characterized marked that they 1 = 4ο2 - one or more apart from a fire protection pane Has discs that have a predetermined breaking point. 9. insulating glazing according to one of claims 1 to 8, characterized in that its panes by a duration elastic adhesive are glued together, DIN 4102 Fulfills. m ψ * tt »ψ « it »www ww _t ^ -4- 10. insulating glazing according to one of claims 1 to 9, characterized in that the spacer consists of a material / that below 700 ⁰ C does not melt. 11. insulating glazing according to claim 10, characterized in that the spacer is reinforced in the corner areas is.