DE102009006062A1 - Infrared-screening laminate, e.g. for car windscreens, comprises two clear, colorless layers and an interlayer which is transparent to visible light and opaque to infrared except for an IR-transparent optical window - Google Patents

Abstract

An infrared-screening, visible light-transparent laminate comprising (A) a colorless, clear, transparent layer, (B) an interlayer which is transparent to visible light but opaque to infrared (IR) (b11), comprising (b1) polyvinyl acetal resin(s) forming the layer and (b2) at least one optical window which is transparent at least to IR radiation and (C) a second colorless, clear, transparent layer. An independent claim is also included for a method for the production of the above laminate, by (i) making a light-transparent precursor for the interlayer (B) with IR-screening effect (b11) containing polyvinyl acetal resin (b1) as layer-forming material, (ii) forming at least one IR-transparent optical window (b2) in this precursor and (iii) bonding the resulting interlayer (B) with two clear, transparent layers (A) and (C) to form the laminate.

Description

The The present invention relates to a novel, infrared radiation shielding, for visible light transparent laminate with a for Infrared radiation transmissive optical window.

Furthermore The present invention relates to a novel process for the preparation an infrared radiation shielding, for visible light transparent laminate.

Not Finally, the present invention relates to the new use of new, shielding infrared radiation, for visible Transparent laminate and of the new method colored, shielding infrared radiation, for visible Light transparent laminate.

modern Laminated safety glass, in particular windscreens for motor vehicles, have an infrared radiation shielding Effect to prevent overheating of the interior. On the other hand, in vehicles increasingly sensors and Cameras used, which are sensitive to infrared radiation are, such as sensors for distance measurement or night vision devices. Their function is but by the Infrared radiation shielding effect of the laminated safety glass panes severely impaired or completely suspended.

in the Case of laminated safety glass based on colored Glasses, such as green glass containing chromium dioxide, or brown glass containing iron sulfides is this problem especially heavy, because the glasses are not just made Be colored for reasons of aesthetics, but also to cause the infrared radiation shielding effect or to reinforce. These colored glasses can but not discolored locally to one for infrared radiation permeable optical window.

From the European patent application EP 1 857 424 A1 is a colored, infrared radiation shielding visible light transparent laminate, which contains a first colorless glass pane, an intermediate layer and a second colorless glass pane or consists thereof. The intermediate layer contains a polyvinyl acetal resin as a layer-forming material, an infrared-ray absorbing material and a coloring material. Although this known laminate can be used instead of laminated glasses based on colored glasses, it can not solve the above problem caused by the infrared radiation shielding effect.

Of the The present invention was based on the object, new, optionally colored, infrared radiation shielding, for visible Light transparent laminates provide the disadvantages of the prior art fix the technology, but the shielding despite their infrared radiation Effect the function of infrared-sensitive Do not interfere with sensors and cameras. Furthermore the new laminates should have high weathering stability, intercoat adhesion, Breakthrough resistance and breaking strength and optionally color stability and after damage a high residual capacity exhibit.

Furthermore The present invention was based on the object, a new Process for producing optionally colored, infrared radiation shielding, to provide visible light for transparent laminates, which remedies the disadvantages of the prior art but that in simple and very reproducible way in high quantities Provides laminates that shield in spite of their infrared radiation Effect the function of infrared-sensitive Do not affect sensors and cameras as well as a high Weathering stability, intercoat adhesion, breakthrough security and breaking strength and optionally color stability and after damage a high residual capacity exhibit.

Not Finally, the present invention was based on the object, a new use for the new, possibly colored, Infrared radiation shielding, transparent to visible light laminates and for those produced by the new method, optionally colored, shielding infrared radiation, for visible light transparent laminates in locomotion for land, sea and air transport as well in the furniture, equipment or construction sector.

• (A) eine erste farblose, klare, transparente Schicht,
• (B) auf der ersten farblosen, klaren, transparenten Schicht eine für sichtbares Licht transparente Zwischenschicht mit Infrarotstrahlung abschirmender Wirkung (b11), enthaltend
• (b1) mindestens ein Polyvinylacetalharz als schichtbildendes Material und
• (b2) mindestens ein für Infrarotstrahlung durchlässiges optisches Fenster, und
• (C) auf der Zwischenschicht eine zweite farblose, klare, transparente Schicht,

in der angegebenen Reihenfolge übereinander liegend enthält.Accordingly, the new colored infrared ray-shielding visible-light transparent laminate has been found, at least

• (A) a first colorless, clear, transparent layer,
• (B) on the first colorless, clear, transparent layer a visible light transparent intermediate layer with infrared radiation shielding effect (b11), containing
• (b1) at least one polyvinyl acetal resin as a layer-forming material and
• (b2) at least one infrared ray transparent optical window, and
• (C) a second colorless, clear, transparent layer on the intermediate layer,

contains one above the other in the order given.

in the Following is the new, infrared radiation shielding, for visible light transparent laminate as »Inventive laminate ".

• (I) eine für sichtbares Licht transparente Vorstufe der Zwischenschicht (B) mit Infrarotstrahlung abschirmender Wirkung (b11), enthaltend mindestens ein Polyvinylacetalharz als schichtbildendes Material (b1), herstellt und
• (II) hierin mindestens ein für Infrarotstrahlung durchlässiges optisches Fenster (b2) erzeugt, wonach man
• (III) die resultierende Zwischenschicht (B) mit mindestens einem für Infrarotstrahlung durchlässigen optischen Fenster (b2) mit zwei klaren, transparenten Schichten (A) und (C) derart haftfest verbindet, dass ein Laminat resultiert, worin die Schichten (A), (B) und (C) in der angegebenen Reihenfolge übereinander liegen.

In addition, the new process for producing an infrared radiation-shielding, visible-light-transparent laminate has been found in which

• (I) a visible light transparent precursor of the intermediate layer (B) with infrared radiation shielding effect (b11) containing at least one polyvinyl acetal resin as a layer-forming material (b1), produces and
• (II) herein generates at least one infrared ray transmissive optical window (b2), after which
• (III) adherently bonding the resulting intermediate layer (B) to at least one infrared-transparent optical window (b2) with two clear, transparent layers (A) and (C) such that a laminate results wherein the layers (A), ( B) and (C) are superimposed in the order given.

in the Following is the new process for producing infrared radiation shielding, visible light transparent laminate referred to as "inventive method".

Not last was the new use of the invention Laminate and the method according to the invention produced laminate in locomotion for the Transport by land, water and air, and furniture, Equipment or construction found what in the following as "inventive Use «is called.

in the In view of the prior art, it was surprising and for the skilled person not foreseeable that the task which was the basis of the present invention, with the aid of the laminate according to the invention, the inventive method and the invention Use could be solved.

Especially it was surprising that the invention Laminate the disadvantages of the prior art no longer but in spite of their infrared radiation shielding effect the function of sensors sensitive to infrared radiation and cameras were not affected. Also pointed the new laminates high weathering stability, intercoat adhesion, breakthrough security and breaking strength and optionally color stability and after damage a high residual capacity on.

Furthermore it was surprising that the inventive Processes the disadvantages of the prior art no longer but in a simple and very reproducible way In large numbers laminates supplied, despite their infrared radiation Shielding effect the function of for infrared radiation sensitive sensors and cameras were not affected, a high weathering stability, intercoat adhesion, Breakthrough resistance and breaking strength as well as possibly color stability and after damage a high residual capacity exhibited.

Not Finally, it was surprising that the inventive Laminates and the process according to the invention produced laminates excellent in locomotion for transport by land, water and air and in the construction sector could be used, taking despite their infrared radiation Shielding effect the function of for infrared radiation sensitive sensors and cameras were not affected, a high weathering stability, color stability, Intercoat adhesion, breakthrough resistance and breaking strength and after damage a high residual capacity exhibited.

The laminates according to the invention have an infrared radiation shielding effect. This effect can be through absorption or reflection the infrared radiation are caused. Preferably, it will caused by the absorption. Preference is given to more absorbed as 50%, in particular more than 70% of the irradiated infrared radiation.

The laminates of the invention can be colored be. In the context of the present invention, this means that they a colorful or achromatic color, but especially a colorful color, can have.

The laminates of the invention are transparent to visible light. Preferably, they have a transmission for visible light> 50%, preferably> 60% and in particular> 70%.

The laminates according to the invention can have different have three-dimensional shapes. So they can be planar or in one direction or several directions of space easily or be strongly bent or curved.

The Surface of the laminates according to the invention can vary widely and depends on the intended use in the context of the use according to the invention. So They can cover an area of a few square centimeters have up to several square meters. In particular, they have one Surface, such as windscreens, side windows, rear windows or glass roofs for motor vehicles usually exhibit.

The Thickness of the laminates of the invention can be wide vary and so perfectly meet the requirements of the case be adjusted. Preferably, the thickness is 4 to 60 mm.

The laminates according to the invention contain a first and a second colorless, clear, transparent layer (A) and (C).

"Clear" means that the layers (A) and (C) no or only a metrological detectable turbidity or haze.

"Transparent" means here, that layers (A) and (C) have a transmission for visible light> 70%, preferably> 80% and in particular> 90% exhibit.

When Materials for the construction of the layers (A) and (C) come basically all materials considered that described above Have property profile and under the conditions of manufacture and use of the laminates of the invention are stable and not damaged.

Preferably be glass and clear plastics, preferably rigid clear plastics, in particular polystyrene, polyamide, polyester, polyvinyl chloride polycarbonate or polymethylmethacrylate.

Prefers Glass is used. Basically all glasses come into consideration as is customary for the production of Laminated glass, in particular laminated safety glass, be used. Preferably, float glass and tempered and partially tempered float glass.

Float glass is a flat glass produced by the float glass process. Both methods for the production of the float glass and the exact meaning of this term are known in the art and need not be further elaborated here. Semi-tempered and tempered float glass is commonly used to produce single-pane safety glass. In particular, alkali-lime-hard glass or soda-lime glass become after DIN EN 572-1 used. Further examples of suitable glasses are described in Römpp-Online 2008 under the keywords »glass«, »tempered glass« or »safety glass« or are from the German translation of the European patent EP 0 847 965 B1 with the file number DE 697 31 2 168 T2 , Page 8, paragraph [0053].

The Thickness of layers (A) and (C) can vary widely and so well be adapted to the needs of each case. Preferably Glasses with standard glass thicknesses of 2, 3, 4, 5, 6, 8, 10, 12, 15, 19 and 25 mm used.

The Area of layers (A) and (C) can vary widely and depends on the surface of the invention Laminates containing them. Accordingly, they are preferred applied the above-described areas.

The Laminate according to the invention also contains an optionally colored, infrared radiation shielding, for visible light transparent intermediate layer (B). Have this the properties »colored«, »infrared radiation shielding «and» for visible light transparent «the respective meanings given above.

The intermediate layer (B) contains at least one polyvinyl acetal resin (b1) as a layer-forming material. Examples of suitable polyvinyl acetal resins (b1) are from the European patent application EP 1 857 424 A1 , Page 3, paragraph [0012], to page 4, paragraph [0020].

Of the Content of the intermediate layer (B) of polyvinyl acetal resin (b1) vary widely and so on the requirements of the case to be perfectly adapted. It is essential that the salary is not may be set so low that the amount of polyvinyl acetal resin (b1) no longer for the formation of a homogeneous, continuous Layer is sufficient. The content is preferably in each case to the intermediate layer (B), at 50 to 99.998 wt .-%, preferably, 55 to 99.9 wt .-% and in particular 60 to 99 wt .-%.

The Interlayer (B) has an infrared radiation shielding effect (b11) and optionally a coloring agent (b12). Especially the intermediate layer (B) has an infrared radiation shielding Effect (b11) and a coloring effect (b12).

The Infrared radiation shielding effect (b11) and the infrared radiation shielding effect (b11) and the coloring effect (b12) can be set in a variety of ways.

The Infrared radiation shielding effect (b11) can be achieved by using at least an infrared radiation shielding material (b11) is set become.

in the Basically, all the usual and known infrared radiation come shielding materials (b11) under the conditions the production and use of the invention Laminates are stable.

The Infrared radiation shielding materials (b11) can in finely divided or molecularly dispersed form in the intermediate layer (B); preferably they are finely divided. Preferably, they have grain sizes in the range of 10 nm to 50 μm, preferably 20 nm to 25 μm and in particular from 30 nm to 10 μm.

Preferably is the infrared radiation shielding material (b11) as finely divided Metals, metal oxides, hydroxides, nitrides, oxynitrides, sulfides, phosphates, pyrophosphates, metaphosphates, polyphosphates, silicates, titanates, -vanadate, -molybdate, -wolframate and -fluoride, transparent electrically conductive Oxides TCO and infrared radiation absorbing organic pigments or mixtures thereof.

Examples of suitable infrared radiation shielding materials (b11) are from the European patent applications EP 1 857 424 A1 , Page 4, paragraphs [0021] to [0022], and EP 1 790 701 A1 , Page 5, paragraph [0036], to page 6, paragraph [0047], or the translation of the European patent specification EP 0 523 959 B1 with the file number DE 692 30 121 T2 , Page 7, line 25, to page 15, line 8, and page 18, line 11, to page 62, line 5, known.

Of the Content of the intermediate layer (B) shielding against infrared radiation Materials (b11) can vary widely and thus perfectly meet the requirements be adapted to the individual case. Preferably contains the intermediate layer (B), in each case based on their total amount, 0.001 to 20 wt .-%, preferably 0.01 to 15 wt .-% and in particular 0.1 to 10% by weight of the material (b11).

The additional coloring effect (b12) can in the most different Way to be set.

So can both effects (b11) and (b12) using at least of a material that has both effects (b11) and (b12) combined. Basically, all the usual ones come and known materials (b11 / b12), which under the conditions the preparation using the inventive Laminates are stable.

Become Materials (b11 / b12) used in general no additional infrared radiation shielding materials (b11) and / or coloring materials (b12) are used.

The Materials (b11 / b12) may be present in the intermediate layer (B) present finely divided or molecularly dispersed; preferably they are finely divided. Preferably, they have grain sizes in the range of 10 nm to 50 μm, preferably 20 nm to 25 μm and in particular from 30 nm to 10 μm.

Examples suitable materials (b11 / b12) are coloring and infrared radiation shielding iron oxide pigments, as described for example in Römpp Online 2008 under the keyword »iron oxide pigments« described become. In addition, iron sulfide pigments and iron and chromium-containing pigments.

Of the Content of the intermediate layer (B) on the materials (b11 / b12) can vary very widely and so perfectly meet the requirements of To be adjusted individually. Preferably, the Interlayer (B), in each case based on their total amount, 0.001 to 30 wt .-%, preferably 0.01 to 20 wt .-% and in particular 0.1 to 10% by weight of a material (b11 / b12).

The but additional coloring (b12) can also help a coloring material (b12) are generated, in addition to the obligatory infrared radiation shielding material (b11) and / or (b11 / b12), in particular (b11).

in the Basically, all the usual and well-known coloring give Materials (b12) considered under the conditions of manufacture and the use of the laminates of the invention are stable. Preferably, the coloring materials (b12) from the group consisting of inorganic pigments and organic Pigments and dyes selected.

The inorganic and organic pigments (b12) can be finely divided available. The organic dyes (b12) can be molecularly dispersed available.

Examples suitable inorganic pigments (b12) are from Römpp Online 2008, "Inorganic Pigments", "Inorganic Colored pigments "," iron oxide pigments "or" chromium oxide (green) pigments ", known.

Examples suitable organic pigments (b12) and dyes (b12) Azo, metal complex, isoindolinone, isoindoline, phthalocyanine, Quinacridone, perinone, perylene, anthraquinone, acridine, diketopyrrolo, Thioindigo, dioxazine, triphenylmethane and quinonaphthalone pigments and dyes.

Especially preference is given to green pigments (b12) and dyes (b12) used.

The content of the intermediate layer (B) of coloring materials (b12) can vary very widely and thus be perfectly adapted to the requirements of the individual case. Preferably, the intermediate layer (B), in each case based on their total amount, from 0.001 to 30 wt .-%, preferably 0.01 to 20 wt .-% and in particular 0.1 to 10 wt .-% of a material (b12).

Of course may also be combinations of at least one of the above described materials (b11 / b12) and at least one of the above described materials (b11) and / or at least one of the above described materials (b12) are used. It can used in each case preferred amounts described above.

In addition, the intermediate layer (B) may contain conventional and known additives (b3) in effective amounts. The additives (b3) have no or only a very low infrared screening effect. Examples of suitable additives are from the European patent application EP 1 857 424 A1 , Page 3, paragraphs [0010] and [0011], and page 4, paragraph [0027], to page 5, paragraph [0037].

The Interlayer (B) can be constructed in different ways be.

So may in a first embodiment of the intermediate layer (B) the materials (b11), the materials or the materials (b11) and / or (b11 / b12) and (b12) homogeneously in a layer of polyvinyl acetal resin (b1) be distributed.

polyvinyl acetal contains acetal radicals having 1 to 2 C atoms, preferably 1 to 8, in particular 2 to 6 C atoms. This is polyvinyl butyral particularly preferred.

In a second embodiment of the intermediate layer (B) can the material (b11) or the material (b11 / b12) predominantly, d. H. to more than 50% of its total amount in a layer of polyvinyl acetal resin (b1), with the remaining amount in a separate layer or in two separate layers on one or both main surfaces the layer of polyvinyl acetal resin (b1) is present. In appropriate Way, the materials (b11) and / or (b12) can predominantly, d. H. to more than 50% of their respective total, in one shift made of polyvinyl acetal resin (b1). The remaining quantities of Materials (b11) and (b12) can then be on or on both major surfaces of the layer of polyvinyl acetal resin (b1). The materials (b11) and (b12) together form a homogeneous layer or in a homogeneous Layer can be contained or they can be separate homogeneous Form layers or contained in homogeneous separate layers be.

In a third embodiment of the intermediate layer (B) can the material (b11) or (b12) homogeneously in a layer of polyvinyl acetal resin (b1) be distributed, the other material (b11) or (b12) then on one or both main surfaces of the layer of polyvinyl acetal resin (b1) as a homogeneous layer or in one homogeneous layer may be present.

A fourth embodiment of the intermediate layer (B) corresponds the third embodiment, only that a subordinate Amount, d. H. less than 50% of the total amount of the material (b11) or (b12) in addition to the total or predominant Amount of each other material (b11) or (b12) in the layer may be distributed from polyvinyl acetal resin (b1).

In a fifth embodiment of the intermediate layer (B) the total amount of material (b11), material (b11 / b12) or the materials (b11) and / or (b11 / b12) and (b12) as homogeneous Layer or in a homogeneous layer on a main surface or on both major surfaces of a layer of polyvinyl acetal resin (b1).

In A sixth embodiment of the intermediate layer (B) can the total amount of material (b11) as a homogeneous layer or in a homogeneous layer on a main surface and the total amount of material (b12) as a homogeneous layer or in a homogeneous layer on the other main surface a layer of polyvinyl acetal resin (b1) are present.

The the list above is not exhaustive but the skilled person can by means of the invention Teach easily further embodiments of the intermediate layer (B) find.

The Thickness of the intermediate layer (B) can vary widely and thus the requirements of the individual case are perfectly adapted. Preferably, the Thickness at 100 μm to 5 mm, preferably 200 μm to 3 mm and in particular 200 microns to 2 mm.

The Surface of the intermediate layer (B) preferably corresponds the surface of the laminate according to the invention.

For the laminate according to the invention is essential that the intermediate layer (B) at least one, in particular a, for Infrared radiation transmissive optical window (b2) having.

"Permeable" means the optical window (b2) has a transmission for infrared radiation, which is significantly higher than the transmission for infrared radiation in the areas of the laminate according to the invention outside the optical window (b2). Preferably the transmission for infrared radiation> 40%, preferably> 50% and in particular> 60%.

The Surface, shape and placement of the for infrared radiation permeable optical window (b2) in the invention Laminate can vary widely and perfectly meet the requirements of To be adjusted individually.

So the area of the optical window (b2) should not be so large that the infrared radiation shielding function of the invention Laminate is impaired. Preferably, the area takes of the optical window (b2) not more than 30%, preferably not more than 20% and in particular not more than 10% of the area the laminate of the invention. The lower one Border for the surface of the optical window (b2) depends on the respective purpose, especially after the requirements of those sensitive to infrared radiation Sensors and cameras placed behind the optical window (b2) are.

The Shape of the optical window (b2) also depends on the respective purpose. Preferably, the shape is circular, elliptic, quadrangular, square, rhombohedral, trapezoidal or triangular.

Also the placement of the optical window (b2) depends on the respective purpose. Preferably, it is placed that on the one hand in the beam path of the sensitive for infrared radiation Sensors and cameras are not other functions disturbs, as for example in a placement immediately in the field of vision of the driver of a motor vehicle would be the case.

In A first embodiment becomes the optical window (b2) of at least one, in particular one, tailor-made use (b21) consisting essentially or entirely of polyvinyl acetal resin (b1), formed in at least one, in particular one, breakthrough (b22).

In this first embodiment of the invention Laminates determine the shape, the area and the placement of the insert (b21) the shape, area and placement of the optical window (b2).

In In a second embodiment, the optical window is located (b2) in at least one layer containing the materials (b11), the materials (b11 / b12) or the materials (b11) and / or (b11 / b12) and (b12) contains or consists of, and a substantially or layer (b1) entirely made of polyvinyl acetal resin, especially covered over the entire surface. The optical window (b2) is from a recess in the layer containing the materials (b11), the materials (b11 / b12) or the materials (b11) and / or (b11 / b12) and (b12) contains or consists of.

What Surface, shape and placement of the optical window (b2) according to the second embodiment, the above statements are analogous.

The second embodiment of the optical window (b2) becomes preferably in the above-described fifth and sixth embodiments of the intermediate layer (B) applied.

First and Second Embodiment of the Optical Window (b2) can be suitably combined with each other, the person skilled in such combinations readily due to the invention Can find teaching.

Especially is the first embodiment of the optical window (b2) used with the snug insert (b21) in the aperture (b22).

The Laminate according to the invention can by means of different Process are produced. According to the invention it is advantageous to use the laminate according to the invention of the process according to the invention.

at the inventive method is in the first Process step a colored, infrared radiation shielding, for visible light transparent precursor of the intermediate layer (B) produced.

The Precursor of the intermediate layer (B) contains the above in detail described components (b1), (b11), (b11 / b12) or In addition, (b11) and / or (b11 / b12) and (b12) the precursor of the intermediate layer (B) at least one of the above described components (b3).

In a first embodiment of the first method step the precursor of the intermediate layer (B) can be prepared by at least one polyvinyl acetal resin (b1) having at least one Material (b11), with at least one material (b11 / b12) or with at least one material (b11) and / or at least one material (b11 / b12) and at least one material (b12) and the resulting Mixture into a film (B) forms. It can also at least an additive (b3) may be added.

The mixing of the ingredients may be accomplished by conventional and known methods and apparatus in solution, dispersion or melt. Examples of suitable mixing units are stirred tank, Ultraturrax, inline dissolver, kneader and extruder. The resulting homogeneous mixture can be prepared in a conventional manner, for example formed by casting from solution or dispersion, calendering, pressing or film blowing to the film (B).

In a second embodiment of the first method step the precursor of the intermediate layer (B) can be prepared by you get a foil (b1) that is either the material (b11) or the material (b12) and which are preferably those described above Way, or a film (b1), which is essentially or entirely of a polyvinyl acetal resin (b1), with at least a layer that contains at least one material (b11), at least a material (b11 / b12) or at least one material (b11) and / or at least one material (b11 / b12) and at least one material (b12) contains or consists of. The layers concerned can be made from the materials themselves or from liquid ones or solid mixtures containing these materials become. For the application of these layers can usual and known methods for the application of liquids and Solids, such as casting from solution or dispersion, Spraying, roller application, printing or powder application, and the corresponding devices are used.

Furthermore can the first and second embodiment of the first step appropriately combined to intermediate layers (B) of the embodiments described above and other embodiments. The expert For example, suitable combinations may be readily understood by reference to the invention Find teaching.

in the second process step of the invention Process is in the precursor of the intermediate layer (B) with a for infrared radiation permeable optical Window (b2) provided.

This can be done by already in the application of the Layer or layers with infrared radiation shielding effect (b11) the area provided for the optical window (b2) the surface of the film (b1) is not coated, so that this area free of the materials (b11) and (b11 / b12) with Infrared radiation shielding effect (b11) remains.

It but it is also possible to produce the optical window (b2), by in the precursor of the intermediate layer (B) a corresponding Breakthrough (b22), for example by punching or cutting, generated and a tailor-made insert (b21), which is essentially or entirely of polyvinyl acetal resin (b1) is used.

Also Here are the embodiments of the second Process step are suitably combined with each other, wherein the skilled person further combinations using the inventive Teaching can easily find.

Especially the optical window (b2) is made by placing in the precursor the intermediate layer (B) has a corresponding breakthrough (b22), for example by punching or cutting, produced and a precisely fitting Insert (b21) consisting essentially or entirely of polyvinyl acetal resin (b1) uses, because there are no additional Coating devices, coating agents and the like Procedural steps must be applied.

in the third process step of the invention Procedure, the resulting film (B) with at least one for infrared radiation permeable optical Window (b2) with two clear, transparent layers (A) and (C) so adherently connected that an inventive Laminate results, wherein the layers (A), (B) and (C) in the in the order given above.

For the third process step, conventional and known methods and devices, as described for example in the European patent specification EP 1 857 424 A1 , Page 5, paragraphs [0042] to [0044].

The resulting laminates according to the invention have an outstanding performance property profile, so that they can be used in a variety of ways. In particular, they are advantageous in means of transportation for the Land, sea and air transport, preferably in motor vehicles, such as cars, trucks and trains, in aircraft and in ships as well as in the furniture, equipment or construction sector, preferably used as transparent components.

Especially the laminates according to the invention are preferred as laminated safety glass in vehicles, in particular as windscreens, side windows, rear windows and glass roofs, especially windshields, for motor vehicles, especially Passenger cars, as well as architectural components in the construction sector, in particular for overhead glazing for roofs, Glass walls, facades, window panes, glass doors, Balustrades, parapet glazing, skylights or walk-in glass, used.

Because of existing in the laminates according to the invention, for infrared radiation-transmissive optical window (b2) placed before or behind, sensitive to infrared radiation sensors or cameras to fulfill their function in full, without the infrared radiation shielding effect of the invention Lami nate is impaired. In addition, they have a high weathering stability, intercoat adhesion, penetration resistance and breaking strength and optionally color stability and after the damage had a high residual capacity.

In the following, the laminate according to the invention will be described with reference to FIGS 1 to 3 explained in more detail. Both 1 to 3 they are schematic representations intended to illustrate the principle of the invention. The schematic representations therefore need not be true to scale. The illustrated proportions therefore do not have to correspond to the proportions used in practice of the invention in practice.

1 shows a laminated safety glass according to the European patent application EP 1 857 424 A1 in cross section.

2 shows a laminated safety glass pane according to an embodiment of the present invention in cross section.

3 shows the top view of the laminated safety glass according to the 2 ,

(A)

farblose, klare Floatglasscheibe,

(B)

Zwischenschicht, enthaltend ein grünes farbgebendes Pigment (b12) und Indiumzinnoxid ITO als Infrarotstrahlung absorbierendem Pigment (b11),

(b2)

für Infrarotstrahlung durchlässiges optisches Fenster aus reinem Polyvinylbutyral,

(B1)

Polyvinylbutyral-Folie, enthaltend ein grünes farbgebendes Pigment (b12) und Indiumzinnoxid ITO als Infrarotstrahlung absorbierendem Pigment (b11) ohne ein für Infrarotstrahlung durchlässiges optisches Fenster (b2),

(C)

farblose, klare Floatglasscheibe,

(ABC)

Laminat mit einem für Infrarotstrahlung durchlässigen optischen Fenster (b2),

(AB1C)

Laminat ohne ein für Infrarotstrahlung durchlässiges optisches Fenster (b2),

(bIR)

blockierte Infrarotstrahlung,

(dIR)

durchgelassene Infrarotstrahlung und

(S, K)

für Infrarotstrahlung empfindlicher Sensor oder empfindliche Kamera.

In the 1 to 3 the reference signs have the following meaning:

(A)

colorless, clear float glass,

(B)

Intermediate layer containing a green coloring pigment (b12) and indium-tin oxide ITO as infrared-absorbing pigment (b11),

(B2)

infrared ray transparent optical window made of pure polyvinyl butyral,

(B1)

Polyvinyl butyral film containing a green coloring pigment (b12) and indium tin oxide ITO as an infrared absorbing pigment (b11) without an infrared ray transmitting optical window (b2),

(C)

colorless, clear float glass,

(ABC)

Laminate with an infrared ray transparent optical window (b2),

(AB1C)

Laminate without an infrared ray transparent optical window (b2),

(BIR)

blocked infrared radiation,

(to you)

transmitted infrared radiation and

(S, K)

Infrared-sensitive sensor or sensitive camera.

The Float glass panes (A) and (C) have dimensions such as those for windscreens, side windows, glass roofs and rear windows in vehicle construction as well as for small, medium or large windows in furniture, equipment or construction sector. The dimensions can several square centimeters to several square meters.

at the polyvinyl butyral film (B1) is conventional and known commercial product, the z. The company Sekisui Chemical or the company Solutia can be obtained. She is the precursor the intermediate layer (B).

The laminate according to the 2 is prepared by cutting the polyvinyl butyral film (B1) to the required size, ie the dimensions of the float glass panes (A) and (C). Thereafter, at the location provided for the optical window (b2), the film (B1) is punched out in a corresponding shape and size, resulting in the opening (b22). Subsequently, the precisely fitting insert (b21) is cut out of a polyvinyl butyral film without an infrared radiation shielding effect and inserted into the aperture (b22). This results in the intermediate layer (B).

Subsequently Both float glass panes (A) and (C) are pre-bonded (Calender roll, snake or vacuum bag method) and a Autoclave method using the with the optical window (b2) provided intermediate layer (B) adherent to each other, so that the intermediate layer (B) between the two float glass panes (A) and (C) and forms the intermediate layer (B).

The laminate according to the 1 is prepared in the same way, except that a polyvinyl butyral film (B1) without breakthrough (b22) and use (b21) is used.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 1857424 A1 [0006, 0035, 0043, 0059, 0097, 0102]
• - EP 0847965 B1 [0031]
• - DE 697312168 T2 [0031]
• - EP 1790701 A1 [0043]
• - EP 0523959 B1 [0043]
• - DE 69230121 T2 [0043]

Cited non-patent literature

• - DIN EN 572-1 [0031]

Claims (17)

Infrared radiation shielding, for visible light transparent laminate, at least containing, in superimposed on the given order, (A) a first colorless, clear, transparent layer, (B) on the first colorless, clear, transparent layer one for visible light transparent intermediate layer with infrared radiation shielding effect (b11) containing (b1) at least one Polyvinyl acetal resin as a layer-forming material and (B2) at least one transparent to infrared radiation optical window, and (C) on the intermediate layer a second colorless, clear transparent layer. Laminate according to claim 1, characterized in that that is transparent to infrared radiation optical Window (b2) no infrared radiation shielding effect (b11) Has. Laminate according to claim 1 or 2, characterized the intermediate layer (B) has a coloring effect (b12). Laminate according to one of claims 1 to 3, characterized characterized in that the infrared radiation permeable optical window (b2) has no coloring effect (b12). Laminate according to one of claims 1 to 4, characterized characterized in that the infrared radiation shielding effect (b11) from an infrared radiation shielding material (b11) and / or from an infrared radiation shielding and coloring material (b11 / b12) is caused. Laminate according to one of claims 3 to 5, characterized characterized in that the coloring effect by at least one Material (b11) and / or at least one material (b11 / b12) caused is. Laminate according to one of claims 1 to 6, characterized characterized in that the infrared radiation permeable optical window (b2) of a precisely fitting insert (b21), which is in Consists essentially or entirely of polyvinyl acetal resin (b1), in an aperture (b22) is formed through the intermediate layer (B). Laminate according to one of claims 5 to 7, characterized characterized in that the infrared radiation permeable optical windows (b2) free of infrared radiation shielding materials (b11) and (b11 / b12). Laminate according to one of claims 6 to 8, characterized characterized in that the infrared radiation permeable optical window (b2) is free of coloring materials (b12). Laminate according to one of claims 1 to 9, characterized in that the layers (A) and (C) of at least a material consisting of the group consisting of glass and plastics. Laminate according to one of claims 5 to 10, characterized in that the infrared shielding material (b11) finely divided metals, metal oxides, hydroxides, nitrides, oxynitrides, sulfides, phosphates, pyrophosphates, metaphosphates, polyphosphates, silicates, titanates, vanadates, molybdates, tungstates and fluorides, transparent electrically conductive oxides TCO and infrared radiation absorbing contains organic pigments and mixtures thereof. Laminate according to one of claims 6 to 11, characterized in that the coloring material (b12) from the group consisting of inorganic pigments, organic Pigments and dyes, is selected. Laminate according to one of claims 5 to 12, characterized in that the infrared radiation shielding and coloring material (b11 / b12) from the group consisting of Iron oxide pigments, iron sulfide pigments and iron and chromium-containing Pigments, is selected. Process for producing an infrared radiation shielding visible light transparent laminate, characterized in that one (I) one for visible Light transparent precursor of the intermediate layer (B) with infrared radiation shielding effect (b11) containing at least one polyvinyl acetal resin as a layer-forming material (b1), manufactures and (II) herein at least one transparent to infrared radiation optical window (b2) generates, after which one (III) the resulting Intermediate layer (B) with at least one for infrared radiation transmissive optical window (b2) with two clear, transparent layers (A) and (C) bonds so strongly that a laminate results, wherein layers (A), (B) and (C) are superimposed in the order given lie. Method according to claim 14, characterized in that that a laminate according to any one of claims 1 to 13 is produced. Method according to claim 14 or 15, characterized in that the infrared radiation-transmitting optical window (b2) is produced by producing in the precursor of the intermediate layer (B) an opening (b22) into which the pass exact insert (b21), which has no infrared radiation shielding effect (b11) is used. Use of the colored, infrared radiation shielding, visible light transparent laminate according to a of claims 1 to 13 and of the method according to one of claims 14 to 16 produced, colored, infrared radiation shielding, visible light transparent laminate in means of transport for land transport, water and to the air as well as in the furniture, equipment or building sector.