NL194011C - Composite glazing panel with high acoustic damping and manufacturing method. - Google Patents

Description

1 194011

Composite glazing panel with high acoustic damping and manufacturing method

The invention relates to a composite glazing panel with a high acoustic damping, provided with two plates of glass-like material and at least one air layer layer, which air layer is enclosed between the two plates of glass-like material.

There is a demand for glazing panels that provide a high degree of acoustic damping, and various types of glazing panels have been proposed to meet this demand. In particular, hollow glazing panels are known, such as gas (eg air) filled panels and vacuum panels, as well as laminates such as those of which the adhesive resin has a fairly pliable nature to provide a damping effect. Both the hollow and laminated panels can be provided with plates of asymmetrical thickness in order to improve the acoustic damping at certain frequencies. It is of course known to include one or more laminated window panes in a hollow glazing panel. Such panels have certain drawbacks which make them unsuitable for use under certain conditions where it would be desirable to provide a high degree of acoustic insulation.

Gas-filled hollow panels have acoustic damping, which is largely determined by the "thickness" of the gas-filled space between the plates. For high damping, the space between the plates must be quite large, and this can cause problems in the manufacture and installation in the window frame By way of example only, such panels, due to their thickness, are unsuitable for application in thin partitions, while vacuumed hollow panels can provide good damping with a relatively close spacing between the plates space, such a vacuum tends, especially with fairly large panels, to leave the glassy plates of the panel hollow, and this may cause an undesired reflection effect.

Laminated glazing panels provide a damping that is broadly dependent on their mass. High damping requires a high specific mass (i.e. mass per unit area). Again, by way of example only, such panels are unsuitable for wall mounting, where weight considerations are an important factor.

A composite glazing panel according to the preamble of claim 1 is known from US patent 4,610,863. US-4,610,863 discloses a method for manufacturing a glazing panel composed of an at least three-layer laminate with increased acoustic damping, which laminate is composed of two outer plates of glass-like material, between which at least one layer of transparent airgel is enclosed. Included in the plates, the airgel matrices can fill the air gap present in a glazing unit for the purpose of realizing thermal insulation.

The glass plates of a multiple glazing unit according to US-4,610,863 are spaced from each other by a conventional spacer attached to the plates.

A drawback of the method according to the US patent is that the laminate obtained therewith does not behave as a single sheet of one material with one modulus of elasticity when vibrations occur. This will cause a so-called "mass-space-mass" resonance.

The present invention aims to provide a composite glazing panel that provides a very high degree of acoustic damping in relation to its total thickness and specific mass. Another object of the invention is to provide a composite glazing panel that behaves in the case of vibration as a single sheet of one material with one modulus of elasticity.

45 This object is achieved according to the invention by a composite glazing panel with high acoustic damping, provided with two plates of glass-like material and at least one layer of airgel, which layer of air is enclosed between the two plates of glass-like material, characterized in that the plates of glassy material and each airgel layer are bonded together such that they can act as a monolithic laminate, and each airgel layer is bonded with another such layer or with at least one of the sheets of glassy material by means of a binder.

The term "monolithic laminate" is used herein to mean a laminate that is glued together in such a way that it vibrates in the same way as a single sheet of a material with a modulus of elasticity, which can be calculated from the modulus of elasticity and thicknesses of the individual layers of the laminate Such monolithic laminates can be compared to hollow panels and 55 laminates, which are only weakly coupled together so that they behave like a box instead of a sheet during vibration. a monolithic laminate does not produce "mass-space-mass" resonance.

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Such a composite glazing panel provides a very high degree of acoustic damping in relation to its total thickness and specific mass. Such a panel also has the advantage of ensuring that both main surfaces of the airgel layer are protected from atmospheric moisture. Aerogels generally have a high moisture absorption, after which they tend to tear and decay into dust. The edges of such a laminate can be well protected in a manner known per se by the use of a moisture-resistant sealant, such as a silicone-based mastic preparation.

It is noted that German composite specification 3,844,003 discloses a composite glazing panel of interconnected glass layers, of which at least one layer consists of a foam layer formed from an airgel. Photosensitive chemicals have been added to the airgel layer. However, this is not a composite glazing panel such as in accordance with the present invention, the sheets of glassy material and each layer of airgel being bonded together to act as a monolithic laminate.

The present invention further aims to provide a method of manufacturing such a panel 15.

Accordingly, the present invention also provides a method of manufacturing a composite glazing panel with high acoustic damping, characterized in that the sheets of vitreous material and each layer of airgel are bonded together to act as a monolithic laminate, and each airgel layer is bonded together with another such layer or with at least one of the plates of glassy material by means of a binder.

This includes a very simple method of manufacturing such a panel.

The airgel used may consist of an airgel of aluminum oxide, zirconia, tin oxide or tungsten oxide, but preferably consists of an airgel based on silica. In order to form an airgel plate for use in such a laminate, a layer of the appropriate gel is dispersed in a solvent on a suitable molding plate and the solvent is removed from the layer to leave an airgel plate. In a preferred method, a silica gel in alcohol as a solvent is spread on a molding plate, which is then placed in an autoclave. The autoclave is pressurized, and the gel is optionally flooded with liquid carbon dioxide to remove all or most of the alcohol solvent. The pressure in the autoclave is increased to a pressure greater than the critical pressure for the solvent liquid contained in the layer (about 80 bar for alcohol or about 74 bar for carbon dioxide). The temperature in the autoclave is then raised above the critical temperature for that solvent (about 24 ° C for alcohol or about 31 ° C for carbon dioxide). In this manner, it is possible to remove the solvent from the layer without collapsing the silicon dioxide structure to form the airgel, and indeed the airgel structure may contain up to about 98 volume percent voids. The airgel plate resulting from this method is then sandwiched between two glassy plates, and the sandwich construction is glued together as a monolithic laminate to form a panel according to the invention.

Panels according to the invention can be opaque, for example they can be formed as decorative panels 40, which can be colored by the use of dyes in the airgel, or alternatively, but preferably, the sandwich construction is glued together to form a translucent laminate. If the laminate is translucent, it can be used as a window closure or otherwise, where translucency is an important factor. Depending on the thickness of the airgel within the laminate, it may even be transparent.

45 Caution is advised when a prefabricated layer of an airgel is glued to a glass-like plate. If a solvent based adhesive is used, it is likely that the solvent can penetrate the airgel, and this would cause the airgel matrix to degrade much in the same manner as during moisture absorption. Therefore, it is preferred that the adhesive is substantially free from a solvent. It is therefore preferable to use a heat-meltable or meltable adhesive material. Aerogels are well able to withstand the temperatures required for the melting of many heat-softenable adhesive materials. Such a heat-softenable adhesive material may be in the form of a thin plate or film, but it is advantageous if the adhesive is in powder form, as this simplifies handling problems. Such a 55 powdered glue can be easily applied, for instance by an electrostatic spraying technique, which is known per se. Fusible silicone resins are particularly well suited to form a very efficient bond between silica-based aerogels and glassy plates, which are also rich in silica.

In particularly preferred embodiments of the invention, the or at least one of the airgel layers is glued directly to a glassy sheet. This avoids any difficulty in selecting and applying an intermediate layer of adhesive material, and greatly simplifies manufacture. The simplest way to achieve such a direct connection is to use a glass-like plate as a molding plate on which the airgel layer is first formed. In this manner, the or at least one airgel layer is formed directly on the glassy plate so that it is adhered directly thereto. A silica-based airgel will adhere well directly to the glassy silica matrix of, for example, a glass plate.

In some preferred embodiments of the invention, the laminate comprises two airgel layers, each of which is glued directly to a glassy sheet. When assembling two airgel layers, each of which is directly formed on a glassy sheet to form a laminate, a panel can easily be formed which has a very high degree of acoustic damping in relation to its thickness and weight.

The acoustic damping by a glazing panel according to the invention is considered to be largely a result of the very large difference in acoustic impedance between the airgel and the glassy material, due to the very low propagation speed of the sound in the airgel. However, in order to take full advantage of this phenomenon, the airgel layer (s) must not be too thin, and it is therefore preferable that the or at least one of the airgel layers has a thickness of at least 10 mm. 20 possession. Increasing the thickness of the airgel layer is also extremely beneficial for the thermal insulation, if desired. It should be noted, however, that the airgel layers diffuse a significant portion of the light, and therefore the total airgel thickness in a panel should not be too great if a high resolution through the panel is considered important.

In order to fully protect the airgel from possible attack by atmospheric moisture, it is preferred that the airgel be hermetically sealed within the laminate. This can be carried out in many ways, for instance by using an edge seal of the aforementioned mastic type, possibly in conjunction with a gutter-shaped frame, for example of extruded aluminum. Preferably, however, the laminate is hermetically sealed by means of one or more spacers which extend around the panel and are soldered onto the glassy plates of the laminate. This provides a very effective and long-lasting protection of the airgel.

In some preferred embodiments of the invention, where the airgel is hermetically sealed within the laminate, the interior of the laminate is evacuated. This is extremely beneficial from the point of view of thermal insulation, and it may also have a beneficial effect in achieving better maintenance of the very low propagation speed of the sound in the airgel.

Preferred embodiments of the invention will now be described by way of example, referring only to the schematic drawings, in which: Figure 1 shows a step in the manufacture of a panel in accordance with the present invention, and Figures 2 and 3 show respective cross sections through two embodiments of the panel of the present invention.

A glass-like plate 1 of suitable size and shape is provided with a surrounding edge 2 around its circumference (compare figure 1).

The space formed above the plate 1 and inside the edge 2 is then filled with an airgel-forming solution. As shown in figure 1, the plate 1 is then placed in an autoclave 3, which is provided with a gas inlet valve 4 and a gas outlet valve 5, as well as a heating element denoted by 6.

The solution used is an alcogel solution, that is, a solution in alcohol. The gel-forming solute may consist of silica only, or may contain additives of other oxides, for example, aluminum, tellurium, germanium or other materials, to impart special desirable properties to the airgel to be formed.

After the airgel-forming solution is poured out, and any bubbles are removed, the solution is allowed to gel and mature. The alcogel thus formed is flushed with liquid carbon dioxide, which replaces the alcohol in the alcogel solution. This can be done by repeatedly flushing the gel solution at about 18-20 ° C and at a pressure of about 55 bar. This possesses like

Claims (8)

194011 4 advantage, that the next manufacturing step is considerably simplified. The pressure in the autoclave 3 is then raised above the critical pressure of the solvent, 74 bar for carbon dioxide, and the temperature in the autoclave is then raised above the critical temperature, 31 ° C for carbon dioxide. This step is simplified by the substitution of carbon dioxide as a solvent, since if the solvent were to remain alcohol, the required temperature and pressure would be above 240 ° C and 80 bar, respectively. Typical practice temperatures for this process step are about 40 ° C for carbon dioxide and about 270 ° C for alcohol as a solvent. Carbon dioxide is suitably used as a pressurized gas, which is supplied via the inlet valve 4. During the drying of the layer, part of the vapor inside the autoclave can escape via the outlet valve 5, 10 and after drying has ended, a direct reaction with the plate 1 connected rear air layer 7. The airgel layer 7 is then sandwiched between the first plate 1 and a second glassy plate. Figure 2 shows such a panel, in which the airgel layer 7 is adhered to a second glass plate 8 via an intermediate layer of glue 9. Such adhesion is effected by spraying a layer of powdered silicone resin electrostatically on the airgel layer 7, the second plate 8 together. 15 with the glue, and heating the assembly to effect the melting of the resin, so that after cooling the sandwich construction is joined together to form a laminate. The panel is completed by inserting a silicone-based mastic material 10 into the indentation between the airgel layer 2 and the first plate 1, which indentation was left after removal of the surrounding edge 2 (Figure 1). In figure 3 a second embodiment of a panel is shown, which is formed by bonding together two airgel layers 7, each of which are formed on and directly connected to a glass-like plate 1. Like the laminate according to figure 2, the laminate according to figure 3 bonded together by means of an adhesive layer 9, which is suitably formed in the same manner. Each of the glassy plates 1 of Figure 3 carries at the edge a metal layer of copper, which is covered by a layer of solder, together denoted 11. These layers 11 were applied before the airgel layers 7 were formed, and they were covered by the boundary edges 2 during the formation of the airgel layers. After gluing the laminate together, metal spacers 12 are soldered between the metal / solder layers around the periphery of the panel, so that the airgel layers are hermetically sealed against the surrounding atmosphere. If desired, the interior of the panel can then be brought under vacuum. Such panels, either according to Figure 2 or according to Figure 3, provide a very high degree of acoustic attenuation given their overall thickness and weight per unit area, while also providing excellent thermal insulation. In a variant of the embodiment shown in Figure 3, the spacer 12 does not extend directly between the two glassy plates, but is corrugated, so that the path of the thermal connection between these plates is extended around their edges. In another variant of the panel, either according to figure 2 or figure 3, the sealing material 10 according to figure 2 or the metal strip 11 and the spacer 12 according to figure 3 have been omitted. Instead, the two glass plates are "soldered" together by a glass joint. It will be understood that a laminate, as shown in Figures 2 or 3, can be joined 40 with one or a number of other elements to form a panel of much more complex construction, if desired. In particular, such a more complex panel may have one or more additional glass plates, such as 1, which bear a directly formed airgel layer 7. 45 Conclusions Composite glazing panel with high acoustic damping, provided with two plates of glass-like material and at least one layer of airgel, which layer of airgel is enclosed between the two plates of glass-like material, characterized in that the plates of glass-like material and each layer of airgel 50 bound together that they can act as a monolithic laminate, and that each airgel layer is bonded together with another such layer or with at least one of the plates of glassy material by means of a binder. Composite glazing panel according to claim 1, characterized in that an essentially solvent-free, fusible adhesive material is used as the binder for binding the laminate together. Composite glazing panel according to claim 1 or 2, characterized in that a binder is used as a binder for binding the laminate together. 5 194011 Composite glazing panel according to any one of the preceding claims, characterized in that a silicone resin is used as the binder for bonding the laminate together. Composite glazing panel according to any one of the preceding claims, characterized in that the or at least one of the airgel layers is formed directly on the glassy plate so that it is bonded directly thereto. Composite glazing panel according to claim 5, characterized in that the laminate is formed by joining two airgel layers, each of which per se is formed directly on a glassy plate. Composite glazing panel according to any one of the preceding claims, characterized in that the or at least one of the airgel layers has a thickness of at least 10 mm. Method for manufacturing a composite glazing panel with a high acoustic damping according to any one of the preceding claims, characterized in that the sheets of glassy material and each layer of airgel are bonded together so that they act as a monolithic laminate, and that each layer of airgel is bonded together with another such layer or with at least one of the plates of glassy material by means of a binder. Hereby 1 sheet drawing