DE20023247U1 - Window or glazed door with gas-filled double or multiple glazing is filled with mixture of 2 noble gases, e.g. argon and small fraction of helium - Google Patents

Abstract

In a window or glazed door with double or multiple glazing and the cavity between pairs of panes filled with a gas mixture, the gas mixture comprises 2 noble gases.

Description

Copy of the preliminary notification EP 00 890 117.5

Window or glass door

The invention relates to a window or a glass door with double or multiple glass panes, wherein the cavity or cavities between the spaced window glass panes is or are filled with a gas mixture.

In the case of conventional double or multiple glazing, the cavity between the panes of glass is in most cases filled with a gas mixture, which allows relatively good thermal insulation to be achieved compared to single glazing. However, double and multiple glazing of this type still has the disadvantage of considerable heat loss.

The object of the invention is to provide a window or a glass door of the type mentioned at the beginning with which an improvement in the thermal insulation properties of double or multiple glazing can be achieved.

According to the invention, this is achieved in that the gas mixture is formed from a first and a second noble gas.

The mixture of two noble gases according to the invention can significantly improve the thermal insulation properties of the window or glass door according to the invention, in particular by reducing the heat loss factor (k value). The resulting energy saving effect enables a significant reduction in heating costs for residential units equipped with windows and doors according to the invention.

In a further embodiment of the invention, it can be provided that at least one of the inner sides of the glass panes is coated with Mo(IV)-SuIHd.

Such a coating enables a further, additional increase in the thermal insulation provided by the window or glass door according to the invention, wherein the layer thickness is preferably selected such that the transparency of the glass pane is still ensured.

Furthermore, it can be provided that the first noble gas has a proportion of 95 wt.% to 99 wt.% and the second noble gas has a proportion of 1 wt.% to 5 wt.% of the gas mixture.

Such a gas mixture reduces the heat loss factor or k-value of glass windows or doors fitted with conventional window glass or insulating glass to half of the previously achievable value. The relatively small proportion of one noble gas disproportionately increases the heat-insulating effect of the mixture with the other noble gas, which takes up a relatively large proportion within the cavity between the panes.

According to a further variant of the invention, it can be provided that the first noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 97.34 wt.% and the second noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 2.66 wt.%.

This results in a particularly strong increase in the thermal insulation of the window or glass door according to the invention. There is a clear reduction in the heat loss factor to below the limit values previously achieved for windows. In a wide variety of test series, it has been shown that precise compliance with the specified weight proportion is essential, since otherwise the effect of a strong increase in thermal insulation properties cannot be fully achieved. Good sealing of the window and door cavities is therefore necessary in order to enable the aforementioned advantageous effect to be maintained.

According to a further embodiment of the invention, an improvement in thermal insulation can be achieved by adding tetrafluoromethane to the gas mixture.

According to a further variant of the invention, tetrachloroethylene can be added to the gas mixture. This addition increases the thermal insulation achievable by the window or glass door according to the invention.

In a further embodiment of the invention, methane can be added to the gas mixture in order to improve thermal insulation.

According to a further variant of the invention, isobutane can be added to the gas mixture.

This addition increases the thermal insulation achievable by the window or glass door according to the invention.

In a further embodiment of the invention, butane can be added to the gas mixture.

This gas mixture also results in a very effective increase in thermal insulation for windows and doors with double or multiple glazing.

The invention is explained in detail below using exemplary embodiments.

A window or a glass door consists of two or more parallel glass panes that are held in a frame.

The cavity or cavities of the double or multiple glazing are filled with a gas mixture, whereby the windows or doors must be sealed pressure-tight after filling. The internal pressure should be slightly higher than the highest external ambient air pressure so that no air remains in the cavity after filling with the gas according to the invention.

According to the invention, the gas mixture is formed from a first and a second noble gas.

At least one of the inner sides of the glass panes is coated with Mo(IV) sulphide, which enables an additional increase in thermal insulation. Two or more inner sides of the double or multiple glazing can also be provided with a corresponding coating.

The gas mixtures given below are to be understood as examples, whereby the proportions given are not intended to represent a limitation of the invention.

In the examples A to T given below, the choice of noble gases is such that the first noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 97.34 wt.% and the second noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 2.66 wt.%.

Despite the relatively small proportion of the second noble gas, it contributes disproportionately to increasing thermal insulation.

EXAMPLE A 97.34 wt% argon 2.66 wt% helium

EXAMPLE B

97.34% by weight helium 2.66% by weight argon

EXAMPLE C 97.34 wt% Argon 2.66 wt% Neon

EXAMPLE D
97.34% by weight neon 2.66% by weight argon

EXAMPLE E
97.34% by weight argon 2.66% by weight krypton

EXAMPLE F

97.34% by weight krypton 2.66% by weight argon

EXAMPLE G

97.34% by weight argon 2.66% by weight xenon

EXAMPLE H
97.34% by weight xenon 2.66% by weight argon

EXAMPLE I

97.34% by weight krypton 2.66% by weight xenon

EXAMPLE J

97.34% by weight xenon 2.66% by weight krypton

EXAMPLE K

97.34 wt% Krypton 2.66 wt% Helium

EXAMPLE L

97.34 wt% Helium 2.66 wt% Krypton

EXAMPLE M

97.34 wt% Krypton 2.66 wt% Neon

EXAMPLE N
97.34% by weight neon 2.66% by weight krypton

EXAMPLE O
97.34% by weight neon 2.66% by weight helium

EXAMPLE P

97.34% by weight helium 2.66% by weight neon

EXAMPLE Q
97.34% by weight neon 2.66% by weight xenon

EXAMPLE R
97.34% by weight xenon 2.66% by weight neon

EXAMPLE S

97.34% by weight helium 2.66% by weight xenon

EXAMPLE T 97.34 wt.% Xenon 2.66 wt.% Helium

The following gases and mixtures thereof have proven to be advantageous additives to the aforementioned gas mixtures, whereby a further increase in thermal insulation could be observed.

Tetrafluoromethane (CF4) Tetrachloroethylene (C2CI4) Methane (CH4)
Isobutane (2-methylpropane) butane (C4H10)

Claims (9)

1. Window or glass door with double or multiple glazing panes, wherein the cavity or cavities between the spaced window glass panes is or are filled with a gas mixture, characterized in that the gas mixture is formed from a first and a second noble gas. 2. Window or glass door according to claim 1, characterized in that at least one of the inner sides of the glass panes is coated with Mo(IV) sulfide. 3. Window or glass door according to claim 1 or 2, characterized in that the first noble gas has a proportion of 95 wt.% to 99 wt.% and the second noble gas has a proportion of 1 wt.% to 5 wt.% of the gas mixture. 4. Window or glass door according to claim 3, characterized in that the first noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 97.34 wt.% and the second noble gas is formed from one of the group helium, neon, krypton, argon and xenon with a proportion of 2.66 wt.%. 5. Window or glass door according to one of claims 1 to 4, characterized in that tetrafluoromethane is added to the gas mixture. 6. Window or glass door according to one of claims 1 to 5, characterized in that tetrachloroethylene is added to the gas mixture. 7. Window or glass door according to one of claims 1 to 6, characterized in that methane is added to the gas mixture. 8. Window or glass door according to one of claims 1 to 7, characterized in that isobutane is added to the gas mixture. 9. Window or glass door according to one of claims 1 to 8, characterized in that butane is added to the gas mixture.