DE102011004178A1 - Fire resistance improved glass sheet and method of making same - Google Patents

Abstract

The invention relates to a fire resistance-improved glass pane which comprises at its edges a layer of material which removes microcracks when applied to the glass. It also relates to a glass frame assembly comprising a fire resistance improved glass sheet and a method for improving the fire resistance of a glass sheet.

Description

The invention relates to a fire resistance improved glass sheet, which comprises at its edges a layer of material which removes microcracks when applied to the glass. It further relates to a glass frame assembly comprising a fire resistance improved glass sheet and a method for improving the fire resistance of a glass sheet.

Refractory tempered glasses are known in the prior art in which the edges are treated by a costly grinding and polishing process to prevent microcracks. These microcracks may be the cause of premature destruction of the glass in case of fire. The treatment process is expensive and it is possible that new microcracks will be created in the treated glass. Alternatively, fluoric acid etching is used in the prior art to remove microcracks after biasing the glass.

In addition, a number of methods provide refractory to commonly tempered float glass by minimizing the temperature gradient between the interior portions of the annealed glass surface and its edges. This can be z. B. by using certain thermally conductive elements. However, even in these cases, sudden breakage of the glass may occur in the event of fire if invisible microcracks have been produced (if any) during the processing of the glass surfaces. By means of this procedure, a fire test usually reaches a fire resistance class not exceeding thirty minutes in a fire test.

Another method of reducing the risk of premature breakage in the case of fire is to anneal the glass twice and / or use other, more suitable annealing methods. In this method, glasses that contain nickel sulfide or other invisible flaws regularly break during the second tempering process. As a result, the glass surfaces that have survived the process are more likely to pass a fire test. On the other hand, this method does not increase the fire resistance time.

The object of the invention was to provide a further fire resistance improved glass.

This object is achieved by a fire resistance-improved glass pane, which at its edges comprises a layer of a material which, when applied to the glass, etches it in such a way that micro-cracks are removed.

"Edges" in the present application is to be understood in particular as the region of the glass pane which (as a rule perpendicular) is angled to the two largest surfaces of the body which is formed by the glass pane.

By etching, it becomes possible to effectively eliminate microcracks. In this case, it is preferred that the material forming the layer comprises SiO ₂ , filling material, preferably in the form of metal powder, alkali metal oxides and organic material.

It is particularly preferred that the layer is formed by applying to the edges of the glass sheet a mixture of components on the edges of the glass sheet having the following composition:
Metal powder: 50.0-75.0% by weight, preferably 55-70% by weight, particularly preferably 60% by weight.
Water: 17.5-35.0% by weight, preferably 25-33% by weight, particularly preferably 30% by weight
Silica: 3.4-7.3% by weight, preferably 4.5-6% by weight, more preferably 5.64% by weight
Dialkalimetalloxid: 1.31-2.85 wt .-%, preferably 1.6-2.5 wt .-%, particularly preferably 2.19 wt .-%
Organic additive: 0.5-5.0% by weight, preferably 1.5-3% by weight, particularly preferably 2.17% by weight

The wt .-% are each based on the total weight of the mixture.

It is preferred that the metal powder comprises or consists of Ag, Al, Cu, Sn, Zn or their mixtures or alloys.

Also preferred is that the organic additive comprises or consists of acrylic resin or styrene-butadiene latex.

Preferably, the dialkali metal oxide comprises or consists of Na ₂ O or K ₂ O. The preferred material for application to the glass has a number of advantages. These relate in particular to the embodiments characterized as being preferred:
In addition to etching to remove microcracks, the material is designed to fill larger gaps in the glass as it hardens, possibly resulting in failure of the glass in the event of fire loading. This gap filling is made by a glassy but elastic substance, through which the whole area of the glass edges is homogenized so much that the risk of cracking and subsequent breakage in fire is significantly reduced. The substance is applied as a thin layer, preferably after the bias of the glass, and more preferably with complete coverage of the edges on all sides of the glass sheet.

Another advantage of the preferred material to be applied is to be seen in its dual function: during the first phase of a fire, when the glass surface is exposed to a significant thermal gradient between the center and the edges of the glass, there is increased resistance due to the elimination of microcracks. At the same time, the layer resulting from the material causes a markedly increased resistance time during the later phases of the fire in which the glass already passes to become softer and could slide out of the frame without the particular effect of the layer to be provided according to the invention.

The improvement of the resistance time is achieved by several effects of the preferred material to be applied. For one thing, the material tends to expand when exposed to high temperatures. As a result, the glass is held firmly in the frame and this prevents slipping out. Furthermore, the sheet material begins to react with the glass at high temperatures to increase the melting point around the edges, thus preserving this edge region from premature softening. This effect is further enhanced by another advantage of the material: in particular, the high metal filler content makes the material a heat conductor. As a result, it is able to dissipate heat from the side facing the fire to the side facing away from the fire. At the same time, the heat conduction effect increases the radiating area for (superfluous) heat.

For the purposes of the invention, it is preferable to improve the radiation effect (cooling effect) of the layer material to be used according to the invention by applying the layer on the edges such that it not only covers the edge surface as defined above, but also covers a strip which 5 to 30 mm, preferably 15 to 22 mm of the main surfaces of the glass sheet circumferentially covered. For the purposes of the invention, it is preferred that, in the case where the glass is framed, this covering width relates to the glass surface which lies outside the usual frame depression. Of course, it is within the meaning of the invention that the area of the main surfaces of the glass pane located in the recess is also covered in this case by the layer material to be used according to the invention. With this arrangement, the heat is transported from the edges of the disk to areas where it can be radiated into the room. This also has the advantage that any existing frame can also be better placed in terms of its heat load.

Another advantage of the preferred material to be used according to the invention is that after hardening it protects the glass sheet during processing on the (particularly sensitive) edges. In addition, the glass can be given a decorative effect in that the material to be applied or the hardened layer can be designed so that it can convey golden or silvery color effects or any other desired color impression.

Preferred in the context of the invention is a fire resistance improved glass pane, was used in the toughened glass. Toughened glass already has an increased resistance to fire per se.

It is further preferred that the toughened glass was produced in an annealing process using air which had been cooled to ≦ 0 ° C. before contact with the glass during annealing of the glass.

This annealing process gives (float) glass a higher degree of preload than that usually achieved with normal annealing techniques. It is preferred that for cooling the air used in the annealing this is passed over or through a device so that it comes into contact with solid carbon dioxide. In this way, the air can be effectively cooled down in terms of costs and devices effectively and used in the annealing process. In this way, it is possible that the glass surface is cooled down effectively and faster, whereby the mechanical and thermal stability, in particular the bending load is significantly enhanced.

It should be noted that the object of the invention can also be solved by an improved tempered glass alone, without necessarily the edges of the glass must be covered with the present invention to be provided layer. Thus, here is an alternative, but of course with the inventively provided layer can be combined to improved effects.

Part of the invention is further a glass frame assembly comprising a glass sheet according to the invention and a frame member for supporting the glass sheet, wherein the frame member comprises a recess for receiving the glass sheet, and wherein on at least a part of the glass pane facing sides of the frame member and / or the inner sides of Deepening for receiving the glass pane one or more heat conducting elements are provided.

In this glass-frame arrangement, the heat-conducting take over a supporting Function to the layer material to be provided according to the invention. In this case, the layer material can effectively transfer its heat to the heat-conducting elements, as a result of which the emission surface can also be increased for superfluous heat. As such Wärmeleitelement are preferably use aluminum baffles. These additionally have the advantage that they can be softened and finally melt on the regions facing the heat source, with suitable attachment with high, long-lasting heat stress, as a result of which the heat conduction in the later phases of the fire can be effectively interrupted. In this context, it is of course preferred that an insulating layer is provided below the heat-conducting elements to the supporting elements of the frame member.

A further advantage of the guide elements is that the layer to be provided according to the invention can optionally be hidden beneath them.

For the purposes of the invention, it is preferred that the glass for the glass pane is a glass with a low iron content so-called "white glass".

Part of the invention is the use of the preferred material described above for improving the fire resistance of a glass sheet.

Furthermore, a component of the invention is a method for improving the fire resistance of a glass pane, comprising the step:
Applying a mixture comprising or consisting of:
Metal powder: 50.0-75.0% by weight,
Water: 17.5-35.0% by weight
Silica: 3.4-7.3% by weight
Dialkali metal oxide: 1.31-2.85% by weight
Organic additive: 0.5-5.0% by weight,
in each case based on the total weight of the mixture
on the edges or part of the edges of the glass.

It is of course further preferred that the materials further preferred above are also used for the process according to the invention.

For the purposes of the method according to the invention, it is possible to apply the mixture to be used according to the invention by means of suitable brushes or brushes. Alternatively, it is possible to apply the material directly in a flowable state and immediately thereafter dry at elevated temperatures. Alternatively, it is of course also possible to immerse the glass material in the mixture to be applied. This also applies as applying the invention. Of course, the dipping operation is performed so that only the portion of the glass is covered with the layer-forming material in which it is desired. Also during the dipping process, it is preferred that drying takes place immediately after dipping at elevated temperatures.

Another alternative method of application is to apply the mixture to be applied by means of a strip of organic or inorganic tissue, e.g. As fiberglass apply, wherein the strip is impregnated with the material to be applied.

The attached figure represents a section of an inventive glass-frame arrangement. Here, the reference numerals

LIST OF REFERENCE NUMBERS

1

Glass pane (here white glass, pre-tensioned, 15 mm)

3

Adhesive tape, double

5

Aluleitblech

7

Insulation material (here aluminum silicate fibers (eg Fiberfrax) 2 × 16 mm)

9

Insulation material like 7 here 8 mm strips pressed on 6 mm

11

Padding, 3 mm,

13, 14, 15

Steel tubes for the frame element

17

Plastic stopper

19

Spacer steel

In the 1 If the layer provided according to the invention is not explicitly recognizable, it is however located between the adhesive tape 3 and the glass pane 1 , By means of the glass-frame arrangement according to the invention, as in 1 exemplified, the fire resistance of the glass 1 significantly improved. This is done on the one hand by the heat-conducting effect of the inventively provided layer on the other by the special mode of action of the Aluleitbleche that provide in combination with the invention to be provided layer for improved heat distribution. During the initial phase of a fire, the coating and aluminum sheets conduct 5 as heat-conducting elements heat to the edges of the glass 1 , This will cause the temperature gradient from the center of the glass 1 to the edges of the glass 1 reduced. For a longer period of fire, they melt to the glass 1 Aluleitbleche aligned 5 , This causes a reduction of the heat supply to the edges and also to the frame, since now the underlying under the guide elements insulating layer ( 7 . 9 ) is exposed to the main heat radiation direction. The reduced inflow thus leads to a delayed softening of the glass 1 and also the frame element here in particular the steel pipes 13 . 14 . 15 ,

At the same time, the view to be provided according to the invention is capable of prolonging the action of heat on the glass pane 1 to fix more within the recess of the frame member, as it expands. In addition, the layer reacts with increasing heat exposure time with the edges of the glass sheet 1 and thus increases the melting point of the glass. This delays a softening of the glass edges out and thus reduces the risk of slipping out of the glass sheet from the frame element. Thus, not only the short-term fire resistance is improved, but also significantly increases the fire resistance time.

Claims (6)

Fire resistance improved glass pane, characterized in that it comprises at its edges a layer of a material which, when applied to the glass, etches it to remove microcracks. A fire resistance improved glass sheet according to claim 1, wherein tempered glass is used for the glass sheet. The fire resistance-improved glass sheet according to claim 2, wherein in the annealing of the glass, air was used which was cooled to ≤ 0 ° C before contact with the glass. A fire resistance improved glass sheet according to any one of the preceding claims, wherein the material forming the layer comprises SiO ₂ , filler preferably in the form of metal powder, alkali metal oxides and organic material. A glass frame assembly comprising a glass sheet according to any preceding claim and a frame member for supporting the glass sheet, the frame member comprising a recess for receiving the glass sheet, and wherein on at least a portion of the glass sheet facing sides of the frame member and / or the inner sides of Deepening for receiving the glass pane one or more heat conducting elements are provided. A method of improving the fire resistance of a glass sheet, comprising the step of: Applying a mixture comprising or consisting of: Metal powder: 50.0-75.0% by weight, Water: 17.5-35.0% by weight Silica: 3.4-7.3% by weight Dialkali metal oxide: 1.31-2.85% by weight Organic additive: 0.5-5.0% by weight, in each case based on the total weight of the mixture on the edges or part of the edges of the glass.

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