DE102018111342A1 - Grout, use of grout and method of grouting - Google Patents

Abstract

The invention relates to a grout, in particular for joints to be filled in-house, drywall, window construction and the like, wherein the grout is a grout based on an acrylate or a mixture of at least two acrylates and that the grout is light-curing or that the joint compound is curable in a dual-cure process, wherein the joint compound is light- and moisture-curing, wherein the joint compound at least one, on exposure to light having a wavelength or wavelength range greater than or equal to 280nm to 600nm starting a polymerization process, photoinitiator The invention also relates to the use of the grout and a method for grouting.

Description

The invention relates to a grout according to the preamble of the first claim, which in particular for the production of joints, e.g. in the context of interior design such. the sanitary and / or kitchen area, the drywall or the installation of windows or doors application, as well as the use of this grout according to claim 17 and a method for grouting a joint with a grout according to the preamble of claim 18th

For example, connecting joints arise according to Wikipedia: "Fugue (construction)" inevitably when two different components meet and the gap formed is to be closed. The best known connection joints are found in the sanitary sector, e.g. as a connection between shower tray, bath or sink to the wall or floor.

The silicones currently used for rooms or areas with high humidity for the production of joints, in particular connecting joints are water-resistant, but have a long curing time, are very odor-intensive (elimination of acetic acid) and not paintable. A further disadvantage of the silicone-based grout is that it is not resistant to the decalcifier commonly used in the bathroom, sanitary and kitchen areas. For connecting joints or for filling and sealing expansion joints or stress cracks, acrylic in the form of acrylic grout is used. Conventional acrylic, however, has a long curing time, is only partially water-repellent and should therefore not be used in wet areas in which a high moisture content is recorded. Since conventional acrylic sealants are water-based and dissolve in water, such acrylic sealants are not used in wet areas as connection joints. Due to their water content, they constantly lose moisture over time and harden more and more, causing the known shrinkage cracks.

Unlike silicone, acrylic is odorless and can be painted over. However, even in drywall or window construction, it is usually necessary to close joints by means of joint compounds. For this purpose, inter alia also grout acrylic based application. These also have a long curing time, so that subsequent trades, e.g. Painting, only after a long period of time can be done.

Furthermore, there is a great disadvantage of such joint compounds for drywall or installation of windows, doors or the like in that the elasticity is very low compared to silicone joints and therefore tear or break these joints under mechanical stress.

The DE 20 2008 007 910 U1 describes a grout, which may contain, inter alia, an acrylic resin and used for grout renovation in sidewalk tiles in the outdoor area to ensure a durable and weather-resistant jointing.

In the DE 10 2015 000 237 A1 describes a material for sealing, insulating and / or sealing damaged areas, boreholes in building facades and sealing joints, the material being or having a synthetic resin in the form of acrylic resin and / or a silicone resin in which hollow microspheres of glass, ceramic and / or or glass ceramic are embedded. With the aforementioned material should also be the sealing and creation of joints in the interior especially in the wet area (shower trays, tubs, sinks, shower enclosures of any kind) may be possible.
The above-described materials disadvantageously have a long curing time.

It is also known from the prior art UV-curable materials based on silicone or acrylic, which are cured with a UV lamp (usually mercury vapor lamp), which due to the formation of ozone suction is required. Furthermore, wearing special goggles is required to prevent eye damage from UV radiation. Another disadvantage of the mercury vapor lamps often used for this purpose is the heat development due to the IR radiation, which can lead to problems with temperature-sensitive substrates.

From the publication DE 10 2006 006 334 A1 For example, a urethane acrylate is known, which are outstandingly suitable as actinic radiation and / or thermally free-radically curable materials or for their preparation and which have a low viscosity. Above all, they should be outstandingly suitable as new coating materials, adhesives, sealants and precursors for moldings and films which are curable with actinic radiation and / or free-radically curable, with the description mainly referring only to the coating materials for the coil coating process. The applied, new with actinic radiation and / or thermally free-radically curable coating materials should be cured quickly and without polymerization or with such a low polymerization shrinkage that the desired property profile is not or not appreciably affected with actinic radiation and / or thermal radical new thermosetting coatings, in particular glossy clear transparent and matt transparent primer coatings, glossy opaque and matte opaque basecoats, glossy-clear transparent and matte transparent topcoats, as well as glossy opaque and matte opaque topcoats with an outstanding property profile. Furthermore, the polyurethane acrylates can later be used as raw materials in various end products. These raw materials are then used under the product name "Laromer" for the production of various end products and get only by the right combination with other raw materials the desired properties, which are necessary for the production of the end products (such as sealant). Again and again, the benefits of low viscosity are noted. Among other things, these materials are not suitable as grout because of their low viscosity, since they must not run during application and should have a defined stability. Furthermore, the type of curing for the intended application is not suitable, since the urethane acrylates used in the prior art do not contain an isocyanate group, for example, for a dual-cure process (both reaction under UV-LED radiation as well as post-crosslinking via air humidity ) are necessary.

• a) mindestens ein polyfunktionelles Urethanharz (70-80%) b) mindestens ein monofunktionelles Acrylat (15-20%) c) mindestens ein trifunktionelles Acrylat sowie Additive und Initiatoren,
• d) Rheologieadditiv (4-7%) e) Additive (0-3%) f) Photoinitiator, insbesondere UV-Initiator (0.1 -3%)

Zur Aushärtung wird UV-Licht verwendet, welches jedoch den entscheidenden Nachteil der Ozonbildung aufweist, wodurch eine Absaugung erforderlich ist. Es werden bekannte UV-Lampen oder Blitzlichtlampen eingesetzt.
Diese Zusammensetzung ist für die Herstellung von in-Situ-Fugen (Anschlussfugen) in Nassräumen nicht geeignet.In the publication DE 20 2015 106 261 U1 there is described a UV-curable seal for a housing, in particular an acrylic formulation for producing a UV-curable seal for an aluminum housing in the engine compartment of automobiles. The following components are used:

• a) at least one polyfunctional urethane resin (70-80%) b) at least one monofunctional acrylate (15-20%) c) at least one trifunctional acrylate, as well as additives and initiators,
• d) rheology additive (4-7%) e) additives (0-3%) f) photoinitiator, in particular UV initiator (0.1-3%)

For curing UV light is used, which, however, has the decisive disadvantage of ozone formation, whereby an extraction is required. There are known UV lamps or flashlamps used.
This composition is not suitable for the production of in-situ joints in wet rooms.

The publication DE 6 02004 006 112 T2 describes moisture-curing silicone for gaskets employing moisture-curing organopolysiloxane 32-70% by weight (non-yellowing) and a photocatalyst (titanate). This material should also act as a protective layer at the interface with air. Since no light-curing urethane acrylates are used, a long curing time is recorded.

In DE 69 322 428 T2 UV-crosslinking material for sealing is described, which crosslinks according to embodiment of this document over several days. In this case, an organolithium reagent serves as a catalyst for the preparation of materials with terminal alkoxysilyl (resulting in a terminal silanol). Moisture crosslinking occurs in the Si skeleton via the alkoxy group (organopolysiloxane). The adhesion promoter used is, inter alia, methacryloxypropyltrimethoxysilane, the synthesis of the material being carried out in a complex manner in a reactor. Volatile materials are formed, which are removed in vacuo. Thus, this is a very complex process. A disadvantage is also the UV curing due to the health risks This material is also not suitable for the production of joints in the home.

A polymer mixture - also for joints - is from the publication DE102008000353A1 known, which is composed on the basis of silicones or contains organic polymers and siloxanes. Furthermore, it is also possible to use compounds which release protons upon irradiation with high-energy radiation, such as UV light or electron radiation, with decomposition. According to embodiment 10, the UV curing of a polymer blend with silicone oil to form a tack-free coating or curing under the influence of temperature - here 140 ° C for 5 minutes, where also a tack-free coating is formed.

The US Pat. No. 7,105,584 B2 discloses a mixture of 2 different silicone or polysiloxane components, which is used by the dual-cure method as encapsulation or potting compound. The polysiloxanes used are first exposed to UV and then moisture-initiated curing mechanisms. Due to their elastomeric properties, such compositions offer vibration and shock resistance, corrosion protection and thermal stress protection for sensitive electronic components. In the latter two publications also the known disadvantages of UV-curing materials occur, such as ozone formation and the required suction and curing takes place under the influence of heat. The catalysts mentioned release protons under UV light, which support the reaction, these are not useful in the radical polymerization.

The crucial disadvantage of these conventional materials and sealants is that they require a long curing time of usually several hours to days, and either moisture-curing (long curing time) or UV-curing. In the case of UV-curing materials, special precautions must be taken to avoid health risks.

In some cases, the materials disclosed in the prior art are not suitable for grouting in the sanitary or kitchen area, or would be available after grouting the example provided with a silicone joint shower only after a long drying time again.

In the case of UV curing materials alone, shaded areas would not cure.

A quick-hardening grout for the preparation of joints in wet rooms in the context of interior work (for example, sanitary and kitchen area) is not disclosed with the solutions described in the prior art.

The object of the invention is therefore to provide a grout available, with the help of which it is possible in situ (on site) freshly filled joints, especially for the sanitary and / or kitchen area and interior design (eg drywall, window construction, floor construction ), within a few seconds to minutes to cure so that an immediate use or further processing (eg painting) is possible.

This object is achieved with the features of the first and seventeenth claim. Advantageous embodiments emerge from the subclaims.

The grout is especially for joints in wet areas, such as sanitary and / or kitchen areas, and / or for drywall, window or floor construction and thus in particular in the context of interior work for the production of in-situ joints or in-situ fill of Grouts used, wherein the joint compound according to the invention is a material based on an acrylate or a mixture of at least two acrylates, and wherein the grout is light-curing or moisture-curing either only light-curing or in a dual-cure process.
In this case, the Lichtz on the grout mass or a light spectrum has a wavelength or a wavelength range greater than or equal to 280 nm.

For this purpose, the grout has at least one photoinitiator which starts a polymerization process of the acrylate or of the acrylate mixture on exposure to light having a wavelength or a wavelength range greater than or equal to 280 nm to 600 nm.

The grout consists of a clear or translucent or translucent material, if it is light-curing in a one-step process. This is also called a radical process (radical polymerization).
If joints, which are accessible over their entire length and width of a corresponding radiation produced with this grout, harden this already in a one-step process by the action of light (light outside the UV range - especially violet to blue light), if the grout made of a clear, or at least a translucent material. It is possible, for example, to sweep the grout introduced into the joint after smoothing and curing.

Is the grout from a substantially opaque or not or not completely translucent material or filled with the grout in situ with the grout / pulled joint is not accessible over its entire length and / or width of light exposure, the curing takes place in the grout introduced grout in a two-stage curing process in the form of a dual-cure process, in which a first (partial) curing with light and a subsequent curing by moisture curing takes place. This material has, for example, color pigments, by which a certain color of the grout is achieved.

Due to the color pigments used, the curing light does not work through the entire applied thickness of the grout introduced into the joint and it is not possible that the curing light acting on it completely cures the joint sealant. It is therefore realized by the irradiation of the light-curing material with the dual-cure process, first a surface hardening by the action of light.

As a result, the grout is already hardened after a few seconds to minutes so that the room can be returned to a use or that during construction other trades can perform their work. In the further process, the grout can now cure completely by hardening with moisture.

The formulation of the grout based on a mixture of acrylates which is photocurable is described below.
The joint compound consists at least of a material curing in the form of light by the action of a polymerizing radiation in the form of or based on acrylate and at least one photoinitiator.
The joint compound has up to 95% by weight of acrylates or a mixture of different Acrylates on. Urethane acrylate, polyester acrylate, polyether acrylate are present in the joint compound individually or in any desired combinations. In this case, the urethane acrylate is in particular an aliphatic at least partially isocyanate-functional urethane acrylate, if the grout is curable in the dual-cure process.

• - Vorzugsweise 10-80 Gewichts % Urethanacrylat, insbesondere in Form von aliphatischem zumindest teilweise isocyanatfunktionellem Urethanacrylat, vorzugsweise einem mono- und/oder difunktionalen aliphatischen Urethanacrylat,
• - vorzugsweise 0-10 Gewichts % eines Photoinitiators, insbesondere eines Photoinitiators wie (Ethyl (2,4,6-trimethylbenzoyl) phenyl phosphinate),
• - vorzugsweise 5-20 Gewichts % Thixotropierungsmittel, insbesondere pyrogene Kieselsäure, bevorzugt hydrophobe pyrogene Kieselsäure,
• - 0-20 Gewichts % Reaktivverdünner, insbesondere monofunktionelle Acrylate ,
• - 0-25 Gewichts % aliphatische Polyether-Urethanacrylate, insbesondere mono- und/oder difunktionelle Polyether-Urethanacrylate.

The light-curing grout in a radical process consists at least of the following components:

• Preferably 10-80% by weight of urethane acrylate, in particular in the form of aliphatic at least partially isocyanate-functional urethane acrylate, preferably a monofunctional or difunctional aliphatic urethane acrylate,
• preferably 0-10% by weight of a photoinitiator, in particular a photoinitiator such as (ethyl (2,4,6-trimethylbenzoyl) phenyl phosphinate),
• preferably 5-20% by weight of thixotropic agent, in particular fumed silica, preferably hydrophobic fumed silica,
• 0-20% by weight of reactive diluents, in particular monofunctional acrylates,
• 0-25% by weight aliphatic polyether urethane acrylates, in particular mono- and / or difunctional polyether urethane acrylates.

The light-curing and moisture-curing grout in a dual-cure process consists essentially of the same constituents, but the urethane acrylate is at least partially isocyanate-functional.

In addition, the grout according to the invention contains additives such as plasticizers, biocides, preferably 0-5% by weight of a fungicide, adhesion promoters, preferably 0-10% by weight of silanes such as 3- (methacryloxy) propyltrimethoxysilanes, and auxiliaries, such as pigments and dyes, preferably 0-10 % By weight, stabilizers, defoamers, preferably 0-5% by weight. The additives are contained individually or in any combination in the grout.

Pigments and dyes are included for coloration, but the color pigments should nevertheless provide a translucent or at least partially translucent grout to ensure complete or nearly complete cure by exposure to light.

Further additives may be optical brighteners, preferably 0-5% by weight of an optical brightener such as (2, 5-thiophenediylbis (5-tert-butyl-1,3-benzoxazole), UV stabilizers, preferably 0-5% by weight, binder, preferably 0-10% by weight and fillers, preferably 0-10% by weight.
Additives and auxiliaries may be incorporated individually or in combination with the grout according to the invention or contained therein.

The grout according to the invention is partially polymerized in a dual-cure process first under a radical photopolymerization, preferably by means of a radiation near the UV range or outside the UV range, in particular above the UV range, and then in a further curing process by an NCO / OH reaction postcrosslinked. Preferably, the grout of the invention is in a pasty state at room temperature (e.g., at 25 ° C) prior to the curing process.

In a particular embodiment of the invention, the grout according to the invention contains up to 10% by weight of polydimethylsiloxane.

The grout according to the invention is at least partially curable, in particular by means of a radiation or a ray spectrum from the middle UV range and / or or near the upper UV range and / or over the UV range.

At room temperature (e.g., at 25 ° C) and before the curing process, the grout is in a pasty state.

The invention also relates to the use of grout according to the invention for in-situ production or in-situ filling of joints in wet areas such as sanitary and kitchen areas but also in drywall, window construction and floor construction.

By the first curing process of the joint compound by the photopolymerization upon exposure to radiation - preferably by means of light - the grout already hardens to 40-80% in particular. Postcrosslinking then takes place, for example, for several hours by moisture curing, in which case immediate use or further processing (coating) is possible.

Particular preference is given to using light in the visible wavelength range and thus outside the UV spectrum in a wavelength range above 380 nm in order to avoid health risks.

However, the lower wavelength range of a used radiation or a radiation spectrum can also in the near UV range (near UV-A; Wavelength range 315-380nm) or even in the UV-B range (wavelength range 280-315 nm) extend (see division according to wavelength (DIN 5031-7).) The wavelength range of 380nm is at the border to the visible light.
If light with a radiation spectrum is used for curing the joint material, this radiation spectrum should preferably have a larger proportion of radiation above the UV range, ie with a wavelength range greater than 380 nm or generally only light in the visible wavelength range> 380 nm.

Upon irradiation of the joint material, the photoinitiator provides radiation in a range of in particular 300 to 600 nanometers (nm), preferably in the range of 350 to 480 nm, particularly preferably in a range of 390 to 410 nm and thus outside the UV range (in particular in the violet to blue light range) for hardening the joint material.
In particular, a liquid photoinitiator type I, which starts a reaction at wavelengths between 390 and 410 nm, is used as the added photoinitiator.
Preferably TPO-L is used - Chemical name according to data sheet: ethyl (2,4,6-trimethylbenzoyl) phenyl phosphinate (also referred to as ethylphenyl (2,4,6-trimethylbenzoyl) phosphinate; Synomyme: 2,4,6-Trimethylbenzoylphenylphosphinsäureethylester or Ethyl (2,4,6-trimethylbenzoyl) phenylphosphinate ethyl (mesitylcarbonyl) phenylphosphinate). Possible types are, for example, Speedcure TPO-L (trade name of Lambson) or Omnirad TPO-L (trade name IGM Resins). But there are many other providers.
A first curing of the grout after their introduction into a joint and the subsequent irradiation with light to achieve a usable state takes place in a few seconds to minutes. It can be done, for example, with the aid of a light-emitting device, in particular in the form of a polymerization lamp, such as an LED or an LED chip, which are provided for example in an LED light source, such as an LED lamp.
When using only a light-curing grout with a radical system or even with a grout that hardens in the dual-cure process, it should be ensured that the grout has a high elongation, as with conventional grout materials based on silicone for connection joints in wet rooms ( such as bathroom and / or sanitary and / or kitchen area) is present.
However, the joint compound according to the invention can also be used, for example, in dry construction. Window construction or used in floor construction.
The big advantage here too is the short curing time of the light-curing or light-curing and moisture-curing grout.

According to the invention, only a curing takes place after the application of the joint compound when the radiation of the light-emitting device (in particular the LED) impinges on the joint compound. This results in the possibility of simple repair after application and before curing.
The curing by means of a polymerization lamp is preferably carried out in a light spectrum outside the harmful UV range, in which no protective agents are required, especially in the violet to blue light spectrum.
Thus, no goggles required for UV applications at a distance of less than 80 cm are required, and there is no need to provide suction which must be used in UV radiation, in part because of ozone formation. However, it is also possible to use a light source which emits light in the UV range and light in the visible range. For this purpose, corresponding different LEDs can be used, for example LEDs which emit light in the UV range (eg in the wavelength range of 280 to 380 nm) and LEDs which emit light in the visible wavelength range (eg over 380 to 480 nm) combined in a light source be.

The LEDs in the UV range then preferably have a lower intensity than the LEDs in the visible wavelength range. (However, it may also be sufficient one or more LEDs that emit light only in the UV range, to harden the material or even one or more LEDs that emit only light above the UV range - greater 380nm).
Another advantage of the solution according to the invention is that no unpleasant odor development and no ozone formation in the processing of the joint material according to the invention is recorded.
As a result, the solution according to the invention for on-site grouting is predestined on site by craftsmen and in the DIY sector.
Already after 2-20 s irradiation with the polymerization lamp, a first curing has taken place, which already allows reuse of the space or the grouted areas or further processing. Complete cure in a radical process or in a dual-cure process that requires postcrosslinking through the humidity will take several minutes to hours, depending on how long the light emitting device has been applied.
Even with a light-curing material, the grout introduced into the joint and removed by the light-emitting device does not cure completely, as by exposure to light of the normal lighting of the room and / or by the action of daylight, the joint sealant also cures completely. By the invention, at least on the surface by The light-emitting device in a ready-to-use state curing sealant results in a time savings of about 24 hours on construction sites, because with the existing jointing materials must be maintained after grouting to carry out subsequent processing or until the use usually 24 hours, as the conventional joint material a very long curing time needed.
Advantageously, can be done by the inventive light and moisture-curable grout very fast curing of so filled joints. The grout is for this purpose filled in the joints, the joints are peeled off with a suitable device such as a spatula or joint smoother and the grout already during the smoothing (peeling) or subsequently irradiated with light in a suitable wavelength. For this example, an LED lamp is suitable. Preferably, light in the UV-near range (not in the UV range) or violet, violet to blue or blue light is used. When irradiated with light of a suitable wavelength, the grout hardens within a few seconds to minutes in a usable state. The usual in the art long waiting times of sometimes several days omitted.

According to the method grouting a joint with a grout especially in the context of interior work, drywall, window construction and the like, according to the invention first the grout is introduced into the joint and the grout subsequently by means of at least one light source by light having a wavelength or a wavelength range greater than or equal 280nm to 600nm is irradiated and thereby at least partially hardens.

In this case, the grout introduced into the joint can be smoothed and / or stripped off before being irradiated with light.

The illuminant is moved after the introduction of the grout in the joint or after smoothing and / or removal of the grout along the joint and radiates radiates on the joint compound and hardens it at least partially.

Alternatively, the illuminant may also be moved along the joint during smoothing and / or peeling of the grout, e.g. with the tool for smoothing or peeling and thereby radiate on the smoothed and / or peeled area of the grout and harden it at least partially.

The distance between the light source and the joint mass introduced into the joint is preferably 0.5 to 50 cm.

The emitted output radiation of the light source during the radiation on the grout should be at least 1.5 watts. If the output radiation is chosen to be larger, e.g. 2 to 10 watts, the distance between the bulb and grout can also be increased.

There may be joints, e.g. Connecting joints, expansion joints and the like between two different or the same materials such. Glass, acrylic, stone, tiles, ceramics, metal, plastic, plaster, drywall, etc. are produced.

An essential advantage of the solution according to the invention in the dual-cure process is that, compared with the pure urethane acrylates according to the prior art, moisture crosslinking results in post-crosslinking at points where no or too little light prevents sufficient curing. The material remains liquid or gel-like there and does not reach the required properties of the final product, if no post-curing occurs.
Another advantage of radically curing or dual cure curing sealants is that they are inherently resistant to fungal attack and no addition of toxic biocides or fungicides is necessary.
Advantageously, the lighting means is designed in the form of a flashlight with one or more LEDs, the flashlight torch or a holder prepared thereon preferably being detachably connectable to the stripping element.

After insertion into the joint, the joint compound is removed by means of a joint spatula. During peeling or after, the joint is irradiated with a lamp, which in particular emits light outside the UV range, in particular light in the violet to blue range. Already at a radiation time of a few seconds, the grout hardens so that the space or the region which has been grouted, a re-use can be supplied or the other trades can perform their work.

The second curing process of the dual-cure process is moisture cure, especially by an NCO / OH reaction. R ¹ -NCO + H ₂ O → [R ¹ -NHCOOH] → R ¹ -NH ₂ + CO ₂ , where H ₂ O comes from the humidity.

The resulting amine now reacts with another isocyanate group to form a polyurea group R ¹ -NH ₂ + R ² -NCO → R ¹ -NH-CO-NH-R ² If the curing is not complete, the grout hardens depending on the joint thickness within 6 hours to several days.
Hereinafter advantageous embodiments are described in the use of grout:

In this case, radiation-curing, in particular in the UV-near range (with wavelengths above the UV range) and preferably by means of light in the violet to blue wavelength range curing acrylates and silicones with the wavelength range already described above for realizing the radical process or the first curing process in dual- cure process used.
Although the acrylates are radiation-curing in principle, the type of radiation (UV or non-UV) is irrelevant for the acrylates. The right wavelength is needed to split the photoinitiators because they depend on the wavelength. The photoinitiators then provide for the further reaction (polymerization) of the acrylates.

The grout according to the invention is used in particular for the interior of rooms in buildings or mobile buildings but also of vehicles and preferably used in wet areas such as sanitary and / or kitchen areas, but also in laboratories and workspaces, for example, tiled or otherwise equipped and in which between adjacent vertical and horizontal surfaces, built-in sink, sanitary equipment, laboratory equipment, cabinets and the like, in particular corner joints or connecting joints must be drawn.
The grouting in interior design, such as in the context of drywall, in window construction, in floor construction (eg when laying tiles or natural stone) is possible with the grout according to the invention. This cures when exposed to light by means of radiation, especially in the UV-near range (NOT in the UV range), preferably in the violet to blue or blue light range within a few seconds to minutes either completely or at least partially.
Due to the rapid hardening of the joint compound, the corresponding space in which the joint / joints was pulled can be quickly reused, or be completed by other trades.
A great advantage of the solution according to the invention is also that the grout is free of volatile solvents and in particular VOC-free (volatile organic compounds) and thus contains no volatile solvents which are odor-causing (possibly also harmful to health).

The introduction of the grout according to the invention in a joint can be done by means of conventional joint spraying such as manual gun, battery gun or compressed air gun.
However, it is also possible to use a cartridge with the joint material according to the invention, which is under pressure.

After the introduction of the grout in the joint this is smoothed (eg by means of conventional grout and can be cured either during the smoothing or thereafter, in particular by means of an LED lamp, along the drawn joint with the LED lamp, the smoothed grout is irradiated and that with light in the wavelength range from 300 to 600 nanometers (nm), preferably in the range from 350 to 480 nm, particularly preferably in a range from 390 to 410 nm and thus outside the UV range (in particular in the violet to blue light range).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202008007910 U1 [0006]
• DE 102015000237 A1 [0007]
• DE 102006006334 A1 [0009]
• DE 202015106261 U1 [0010]
• DE 602004006112 T2 [0011]
• DE 69322428 T2 [0012]
• DE 102008000353 A1 [0013]
• US 7105584 B2 [0014]

Claims (23)

Grout, especially for joints to be filled in-situ for interior fitting, drywall, window construction and the like, characterized in that the grout is a grout based on an acrylate or a mixture of at least two acrylates and - that the grout is light-curing or - that the grout can be hardened in a dual-cure process, the grout being light- and moisture-curing. Grout after Claim 1 , characterized in that the grout has at least one, upon exposure to light having a wavelength or wavelength range greater than or equal to 280nm to 600nm a polymerization process starting photoinitiator. Grout after Claim 1 or 2 , characterized in that - the grout consists of a clear or translucent or translucent material and is light-curing or - that the grout consists of a substantially opaque or not completely translucent material and in a dual-cure process with light and moisture-curable curable , Grout according to one of the Claims 1 to 3 , characterized in that the grout consists at least of the following components: - at least one under the action of a polymerizing radiation in the form of light-curing material in the form of acrylate - and at least one photoinitiator. Grout according to one of the Claims 1 to 4 , characterized in that it comprises up to 95% by weight of acrylates in the form of - urethane acrylate, - polyester acrylate, - polyether acrylate individually or in any desired combinations. Grout according to one of the Claims 1 to 5 , characterized in that the urethane acrylate in the dual-cure system is an aliphatic at least partially isocyanate-functional urethane acrylate. Grout according to one of the Claims 1 to 6 , characterized in that the grout additives such as - plasticizer - biocides, - adhesion promoters and - auxiliaries, such as pigments, dyes, stabilizers, defoamers, individually or in combination are added. Grout according to one of the Claims 1 to 7 , characterized in that they are partially polymerized in a dual-cure process first under a radical photopolymerization and then postcrosslinked in a further curing process by an NCO / OH reaction. Grout according to one of the Claims 1 to 8th , characterized in that the grout is at least partially curable by means of a radiation or a ray spectrum from the middle UV range and / or or near the upper UV range and / or over the UV range. Grout according to one of the Claims 1 to 9 , characterized in that in a free-radical process, light-curing grout consists at least of the following components: - 10-80% by weight of urethane acrylate, - 0-10% by weight of a photoinitiator - 0-20% by weight of reactive diluent, - 0-25% by weight of polyether Urethane acrylates and - 5-20% by weight of thixotropic agent. Grout according to one of the Claims 1 to 10 , characterized in that in a dual-cure process light- and moisture-curing grout consists at least of the following components: - 10-80% by weight of urethane acrylate, - 0-10% by weight of a photoinitiator - 0-20% by weight of reactive diluents, 25% by weight polyether urethane acrylates and 5-20% by weight thixotropic agent, wherein the urethane acrylate is at least partially isocyanate functional. Grout after Claim 9 or 11 , characterized in that the joint material - aliphatic urethane acrylates, in particular mono- and / or difunctional aliphatic urethane acrylates and / or - type 1 photoinitiators, preferably TPO-L (ethyl (2,4,6-trimethylbenzoyl) phenyl phosphinates) and / or Reactive diluents in the form of monofunctional acrylates, in particular isobornyl acrylate and / or aliphatic polyether urethane acrylates, in particular mono- and / or difunctional polyether urethane acrylates and / or thixotropic agents in the form of silica, in particular fumed silica, in particular hydrophobic fumed silica. Grout according to one of the Claims 1 to 12 , characterized in that as additives - 0-10% by weight of silanes as adhesion promoters, 0-5% by weight of at least one optical brightener, 0-5% by weight of at least one UV stabilizer, 0-10% by weight of at least one binder, 0-10% by weight of at least one Filler, 0-5% by weight of at least one fungicide, 0-5% by weight of at least one defoamer and 0-10% by weight of pigments and / or dyes individually or in any combination. Grout according to one of the Claims 1 to 13 , characterized in that - as adhesion promoter silanes 3- (methacryloxyl) propyltrimethoxysilane and / or - as optical brightener 2, 5-thiophenediylbis (5-tert-butyl-1, 3-benzoxazole and / or is used. Grout according to one of the Claims 1 to 14 , characterized in that in the grout up to 10 weight% polydimethylsiloxane are included. Grout according to one of the Claims 1 to 15 , characterized in that it is in a pasty state at room temperature (eg at 25 ° C) prior to the curing process. Use a grout after Claim 1 for joints to be filled in-situ for interior fitting, drywall, window construction and the like. Method for grouting a joint with a grout after Claim 1 , in particular in the context of interior work, drywall, window construction and the like, characterized in that the grout is introduced into the joint and that the grout is then irradiated by means of at least one light source by light having a wavelength or wavelength range greater than or equal to 280nm to 600nm and thereby at least partially hardens. Method according to Claim 18 , characterized in that the grout introduced into the joint is smoothed and / or stripped off before being irradiated with light. Method according to Claim 18 or 19 , characterized in that the lighting means is moved after the introduction of the grout in the joint or after smoothing and / or removing the grout along the joint and thereby radiates on the grout and this at least partially hardens. Method according to Claim 18 or 19 , characterized in that the lighting means is moved during the smoothing and / or removal of the grout along the joint and thereby radiates on the smoothed and / or peeled area of the grout and this at least partially hardens. Method according to one of Claims 18 to 21 , characterized in that the distance of the illuminant to the grout introduced into the joint is 0.5 to 50 cm. Method according to one of Claims 18 to 22 , characterized in that_ the emitted output radiation of the illuminant during radiation to the grout mass is at least 1.5 watts.