EP2168734A1 - Method for producing a veneer carpet - Google Patents

Abstract

The method involves preparing two veneer strips to be joined, and applying an aqueous bonding agent on an edge of one of the strips. The bonding agent is dried, and energy in the form of hot air, infrared radiation, high frequency radiation and/or microwave radiation is supplied to the bonding agent. The strips are joined at the edge, where the bonding agent is maintained at a temperature of 55 degree Celsius. The bonding agent is hardened, where the bonding agent is free from formaldehyde.

Description

The invention relates to a method for producing a veneer carpet from at least a first veneer strip and a second veneer strip, wherein the veneer strips are interconnected at their edges.

It is known to produce a veneer carpet from individual veneer strips by joining at their longitudinal edges, which is then used for example in the furniture industry for the production of veneer furniture. To join individual veneer strips together to form a veneer carpet, a molten hot-melt adhesive thread is zig-zagged over a gap between two veneer strips arranged next to one another. In this case, a glue is previously applied to the abutting edges of the veneer strips and then the veneer strips are connected by pressing against each other at their abutting edges by means of the glue, wherein at the same time the heat-bonding thread is applied in zigzag on the veneer back side.

Many types of glue or binder for joining veneer wood are already known. Binders based on urea or phenol or melamine-formaldehyde resins are best processed so far. These have the advantages that they can be easily and evenly applied to the edges of the veneer strip, dry there quickly and very easily, for example by heating, can be activated. However, formaldehyde has the disadvantage that it is harmful to human health.

Especially because of the possibility of toxic damage to humans in contact with formaldehyde or inhalation of fumes formaldehyde, it would therefore be desirable to use in the production of veneer carpets alternative, not harmful, binder for joining veneer strips.

It is therefore an object of the present invention to provide a method for producing a veneer carpet by joining veneer strips, which produces a harmless from a health point of view and environmentally friendly veneer carpet. Furthermore, the inventive method should be simple and inexpensive and allow a secure connection of the veneer strips to the veneer carpet.

This object is achieved by a method having the features of claim 1. The dependent claims each show preferred developments of the invention.

The inventive method for producing a veneer carpet with the features of claim 1 has the advantage that it is simple and fast executable. In this case, a secure joining veneer stiffeners can be achieved. This is achieved according to the invention by preparing at least one first veneer strip and one second veneer strip in a first step, for example by providing the veneer strips with a parallel cut on the veneer edges and, on the other hand, juxtaposing them at their abutting edges. In a second step, an aqueous binder system is provided and applied to at least one edge of the first veneer strip. Then the applied aqueous binder system is allowed to dry. In a further step, energy is supplied to the aqueous binder system applied to the edge of the first veneer strip and the first and second veneer strips are added to the bindered side. In a final step, the applied aqueous binder system is cured. Preferably, the step of energizing and joining is simultaneous or very short in succession, e.g. at a time interval of 0.1 s.

An essential part of the process according to the invention is the binder system. The binder system is aqueous, ie an aqueous preparation. This means that the solvent of the binder consists largely of water and may further contain water-miscible components, such as mono- and polyhydric alcohols, and other hydrophilic substances. Water as a solvent has the advantage that it represents a safe for humans in normal use solvent on the one hand, so that must be applied to the to be complied with in the manufacture of furniture safety precautions no particularly high standards. Furthermore, there is also a later evaporation Of residual moisture from the veneer carpet for humans completely harmless and therefore not harmful to health. In addition, water is a low-cost solvent compared to organic solvents, which is available almost unrestricted and thus in stock and ready for use at any time.

In addition, the solvent water is characterized by a polar character and thus a high affinity to wood, which is also formed from polar substances from. The wetting of the edge of the veneer strip with the binder system according to the invention is thus very good. The binder system can be easily and homogeneously applied to at least one edge of the first veneer strip, easily distributed without much pressure, without islands of unevenly distributed binder system forming on the surface of the veneer edge of the veneer strip, resulting in incomplete joining of the veneer strips and thus significantly reduced durability of the veneer would result.

It is also essential to the invention that the binder system according to the invention is free from formaldehyde or does not release formaldehyde even after prolonged storage under the given ambient conditions. This makes it environmentally friendly and harmless to humans.

After application of the binder system is allowed to dry according to the inventive method. This can be done in different ways. Here, too, shows a further advantageous property of the aqueous binder system according to the invention over the binder systems used in the prior art based on organic solvents. The solvent water can already be allowed to dry in the air without adversely affecting the environment or people, or blown out by hot air or electric heaters are evaporated.

To a binder system for joining edges of veneer strips are particularly high expectations. The binder system must not only be easy and evenly applicable, but must after curing the edges also connect permanently. The hardened layer must not be too hard, but not too elastic, because otherwise the sheared edges break apart again at the joint due to shearing or slight twisting. The binder system used in the process according to the invention is characterized by optimum application properties and durable good durability. Furthermore, the binder system used according to the invention provides a sufficient adhesive force, so that it is possible to dispense with the application of a zig-zag hot-melt adhesive thread.

According to a preferred embodiment of the present invention, the aqueous binder system is applied to the edge of the first veneer strip and to an edge of the second veneer strip. This has the advantage that in each case a defined amount of binder system is applied to the respective edge to be joined, so that after joining the corresponding edges, an optimal connection of the wetted edges is achieved without excess binder system passes beyond the joint.

In a further preferred embodiment of the present invention, the binder system of the invention comprises at least one polyester and / or a polyether and / or polyvinyl acetate. Polyester or polyether and polyvinyl acetate are polymers that are suitable for adjusting the desired properties of the binder system. They are also distinguished by a largely hydrophilic character, so that they are readily soluble or at least dispersible in the aqueous binder system. Through a variety of chemical adaptation options, they can exert an influence on the application properties and adhesive properties of the binder system. The polyesters or polyethers to be used are not limited in detail and include those composed of different monomers. However, particularly suitable are those polyesters or polyethers which are distinguished by good water solubility or water dispersibility.

In order for the binder system in the process according to the invention to be able to permanently add two juxtaposed edges of veneer strips, energy is supplied to the binder system after application. By the entry of Energy is triggered in the binder system, a reaction that converts the non-volatile components of the binder system into a permanently adhesive binder. In most cases, the addition of energy to a binder system triggers a polymerization reaction, in particular a polycondensation or polyaddition, but also a free-radical polymerization reaction. The feeding of energy in the method according to the invention can take place in different ways and in particular is not restricted to a specific method. Thus, the reaction in the binder can be initiated and carried out by introducing warm air and / or infrared radiation and / or high-frequency radiation and / or microwave radiation and / or by means of contact heating.

According to a further advantageous embodiment of the method according to the invention, the aqueous binder system is heated to a temperature of at least 55 ° C. after application for the step of joining. From a temperature of at least 55 ° C, the reaction is initiated in the binder system. The temperature is not limited to the top, since the components of the binder system are largely insensitive to even high temperatures of about 100 or 150 ° C. The temperature can therefore be adjusted as desired according to the further processing.

According to another preferred embodiment, the binder system used in the process of the invention may contain a crosslinker. Under a crosslinker, according to the invention, e.g. Monomers or oligomers are understood that more than two functional groups. Contain links. With their help, the person skilled in the art can connect linear or branched macromolecules to form three-dimensional networks. As an example, divinylbenzene forms cross-linking bridges via its two vinyl groups. The type of crosslinker is not limited in detail. The skilled person can select them so that the application and adhesive properties of the binder system are optimized.

In a further preferred embodiment, the method according to the invention is characterized in that the aqueous binder system particles with a Particle size of about 0.1 .mu.m to 200 .mu.m, preferably 0.1 .mu.m to 50 .mu.m contains. The particle size is measured here at the widest range of the respective particle. A particle size of the particles in the aqueous binder system adjusted to a range of about 0.1 μm to 200 μm has the advantage that the type of application of the binder system to at least one edge of the first veneer strip is not restricted in detail. This makes it possible even to atomize the binder system without sticking the nozzles used. A further advantage of such fine particulate binder systems is that these binder systems remain homogeneous and stable over the long term, ie also stable on storage, because the particles do not settle in the aqueous preparation as a sediment following their gravitational force. Even with particles with more than 200 microns at its widest point settling in the aqueous solution can no longer be optimally counteracted. Particles with a particle size of less than 0.1 microns, however, are technically very difficult and can be realized only with enormous effort, which is not economically responsible. Preferably, the particles have a particle size of 0.1 .mu.m to 50 .mu.m. This particle size is optimal. The particles remain in suspension in the aqueous binder system very well and do not stick to the nozzles during atomization.

In a preferred embodiment, the inventive method is characterized in that the aqueous binder system at 20 ° C has a viscosity of up to 5000 mPas, preferably between 1500 mPas and 2500 mPas. The viscosity is measured at 20 ° C by means of a Brookfield viscometer, RVT spindle 3, at 20 rpm. A viscosity of more than 5000 mPas means that the aqueous binder system can not be applied optimally to the edges to be joined due to its viscosity. Even when the composition is rolled by means of some pressure, the aqueous binder system tends to disperse in an inhomogeneous manner and not spread on the edge, as desired. In contrast, a viscosity of less than 1500 mPas causes the mass of the edge to be joined to drip off after application.

According to a preferred embodiment, the application properties of the aqueous binder system are correspondingly selected such that the aqueous binder system penetrates into the open pores at the edge of the veneer strip can. The penetration of the binder system in the pores or open pores on the edge of the veneer strip better anchorage of the binder system is produced with the veneer strip, which finally after curing of the binder system, the two joined veneer strips are connected to each other much stronger than if only superficially on a binder system the edge of the veneer strip would be applied. Without being bound by theory, it is believed that the anchoring of the binder in the pores of the veneer strip can be so well produced, because just the main solvent water is characterized by very good capillary properties, so preferably penetrates into the pores on the edge of the veneer strip , With the water, the binder system is also introduced into the pores, which remains in the pores there after drying of the water and ensures the excellent anchoring of the binder system with the veneer strip to be joined. The Kapillargängigkeit is much lower in the previously known resin-based systems, so that the specific anchoring effect is not apparent.

As already stated, the method for applying the binder system to at least one edge of the first veneer strip is not restricted in detail. The aqueous binder system can be applied both by means of mechanical devices at the desired location, such as by means of a rolling mill or atomized on the edge of the first veneer strip. While the application by means of mechanical devices is usually less expensive and easier to implement, the atomization offers the advantage that fine mist of the aqueous binder system can be applied to the corresponding edge very uniformly and even in very thin layer thicknesses. By applying very thin layer thicknesses, the minimum required amount of binder system is applied without further binder system to waste. It also prevents excess binder system from dripping from the edge prior to joining.

The Verdüseeigenschaften a binder system are highly dependent on the particle size of the preparation to be atomized. The smaller the particle size, the better and more uniform the atomization. A particle size of about 0.1 μm to 200 microns is to be regarded as very good. The binder system is thus uniformly and uniformly applied to the desired location.

In a preferred embodiment, the aqueous binder system is applied perpendicular to at least one edge of the first veneer strip by means of atomization. By the vertical position or mutually perpendicular arrangement of the nozzle from which exits the aqueous binder system, and the pores or open pores of the edge of the veneer strip to which the binder system is to be applied, is caused that the binder system optimally penetrates into pores of the veneer strip and thus anchored perfectly with the edge of the veneer strip to be joined. It does not matter which shape and shape the pores are. They can be round or even elongated with any inner shape. An opening cross-section of the pores, however, lies in a plane in which the edge also lies, wherein the edge is arranged perpendicular to the veneer surface. By vertical atomization, the aqueous binder system is actively introduced into the pores, so that it penetrates far deeper into the pores and also completely fills the pores. The anchoring is optimal. Such veneer strips have a permanently good joint.

For the atomization of the aqueous binder system according to one embodiment of the method according to the invention, it is advantageous if the rate at which the binder system is applied is about 10 to 50 m / s.

At speeds below 10 m / s, the atomization can not be carried out optimally, so that the pores at the edge of the veneer strip, in which the binder system is to penetrate, are not completely filled completely. At speeds in excess of 50 m / s, the binder system strikes the edge of the veneer strip at such a high speed that much of it bounces off, resulting in increased consumption of aqueous binder system and, incidentally, also dripping plywood strip locations where was not desired.

By means of the method according to the invention, a particularly stable veneer carpet can be provided, whose veneer strips are optimally joined, so that a lasting durability of the veneer carpet can be ensured. Furthermore, the veneer carpet is not a burden on the environment or health damage to living beings and in particular to humans, since no harmful gases exude.

Claims (14)

A method for producing a veneer carpet from at least a first veneer strip and a second veneer strip, which are joined together at their edges, characterized by the steps: - preparing the veneer strips to be joined, Applying an aqueous binder system to at least one edge of the first veneer strip, Drying the applied aqueous binder system, Supplying energy to the aqueous binder system applied to the edge of the first veneer strip, Joining the first and second veneer strips to the edge provided with the aqueous binder system Curing the applied aqueous binder system, wherein the aqueous binder system is formaldehyde-free. A method according to claim 1, characterized in that the aqueous binder system is applied to the edge of the first veneer strip and to an edge of the second veneer strip. Method according to one of claims 1 or 2, characterized in that the binder system contains at least one polyester and / or a polyether and / or polyvinyl acetate. Method according to one of the preceding claims, characterized in that the energy is supplied to the applied aqueous binder system in the form of warm air and / or infrared radiation and / or high-frequency radiation and / or microwave radiation and / or by means of a contact heater. Method according to one of the preceding claims, characterized in that the aqueous binder system for the step of joining to a temperature of at least 55 ° C is heated. Method according to one of the preceding claims, characterized in that the aqueous binder system contains a crosslinker. Method according to one of the preceding claims, characterized in that the aqueous binder system contains particles having a particle size of about 0.1 microns to 200 microns, preferably 0.1 to 50 microns. Method according to one of the preceding claims, characterized in that the aqueous binder system at 20 ° C has a viscosity of up to 5000 mPas, preferably between 1500 mPas and 2500 mPas, wherein the viscosity by means of a Brookfield viscometer with a RVT spindle 3 at 20 U / min is measured. Method according to one of the preceding claims, characterized by the step that the aqueous binder system is introduced into the pores at the edge of the at least first veneer strip. Method according to one of the preceding claims, characterized in that the aqueous binder system is applied to at least one edge of the first veneer strip by means of rolling by means of a rolling mill. Method according to one of claims 1 to 9, characterized in that the aqueous binder system is applied to at least one edge of the first veneer strip by means of atomization. A method according to claim 11, characterized in that the aqueous binder system is applied perpendicular to at least one edge of the first veneer strip by means of atomization. Method according to one of claims 11 or 12, characterized in that the aqueous binder system is applied at a rate of 10 to 50 m / s. Use of a formaldehyde-free aqueous binder system to join veneer strips at their edges to form a veneer carpet.