EP1181987A2 - Method for at least a partial coating of substrates - Google Patents

Abstract

The coating process deposits fluid or paste-form substances such as thermoplastics on a carrier material. The substance is applied by a jet (1) at least partially on the carrier material running along the jet. The jet body is bent transversely to the running direction of the carrier material by temperature difference induction.

Description

The invention relates to a method for applying liquid or pasty substances, in particular thermoplastics, on a carrier material, the substance by means of a nozzle at least partially applied to the carrier material passing under the nozzle becomes.

On the market, for example, there are substrates that are used in the medical field viscous substances are coated. One way to do this coating consists of squeegee processes that are open to the environment and that do not use a Apply nozzle. In many cases, this coating is carried out over the entire surface by means of one against a counter-pressure roller around which the web-shaped carrier material to be coated is performed, employed coating nozzle. The one to be coated Substance is transported under pressure from the outlet gap of the nozzle and onto the passing one Railway laid.

For the coating of carrier materials with later medical, cosmetic or technical use are preferred adhesives, especially preferably self-adhesive compositions used. These preferably belong to the material classes solutions, dispersions, prepolymers and thermoplastic polymers on.

Thermoplastic hot melt adhesives are advantageously used on Based on natural and synthetic rubbers and other synthetic polymers such as examples include acrylates, methacrylates, polyurethanes, polyolefins, polyvinyl derivatives, polyesters or silicones with appropriate additives such as adhesive resins, plasticizers, Stabilizers and other auxiliaries where necessary.

Your softening point should be higher than 50 ° C, the application temperature is in usually at least 60 ° C, preferably between 100 ° C and 180 ° C, respectively 180 ° C and 220 ° C for silicones.

The aim is to apply the quantity of substance to the web across the web width to keep as constant as possible. This becomes fundamental through the rheological interpretation of the flow channels arranged in the nozzle. Typical geometries Here are, for example, the hanger distributor or axially extending distribution channels have a significantly larger cross-sectional area than the radially departing, in Direction of the outlet gap further channels. The disadvantage is that the rheological Design only for a limited viscosity range of the substance to be coated is valid. If there is a deviation, irregularities in the order quantity arise over the web width.

To avoid this or the usable viscosity range of the so designed Various additional measures are taken to expand nozzles. It is known to insert a dust bar in the outflow gap of the nozzle, which in its Height and thus its stowage effect is adjustable. The setting is made using a Large number of control elements, which are arranged at regular intervals along the dust bar are arranged and their number is often up to 30 per meter of coating width is. Screws, thermal bolts or piezo elements are essentially used as control elements used.

As an alternative or in many cases also in addition to the dust bar, the outlet gap in its cross section adjustable. To do this, a lip is usually the gap by adjusting elements, as already mentioned above, by an elastic deformation forced into the desired position. Again, the adjustment of the equal distribution achieved via a large number of control elements.

Furthermore, for the uniformity of the substance application, the gap between the nozzle and Back pressure roller significant. This gap is made by a movable or swiveling Nozzle set. The setting can usually be to the right and left of the lane be done independently.

The section-wise variation of the gap between the nozzle head and Back pressure roller to compensate for order weight errors across the width. This is in usually the one located in the direction of rotation of the counter-pressure roller behind the outlet nip Lip with a bar that can be moved or deformed radially to the counter-pressure roller Mistake. The usual multitude of the above-mentioned control elements should also be mentioned here.

Mechanical shaping devices for the entire nozzle body are also known (Jeck facilities). The path change in the µm range between is used here the middle and the edges of a steel body. As a rule, mechanical adjustment implemented by means of spring force, differential thread position etc. and a counter plate. The resulting deformation path is a controlled variable that the Coating application with 100% polymers is directly proportional.

Segmented coating nozzles are also used, with each segment a separate inflow of the substance and a separate adjustment of the Feed quantity of the substance has. The latter is done by individual dosing pumps or valves realized per segment. By setting the outlet quantity in segments is the homogeneity of the applied weight over the coating width reached.

A disadvantage of all the above-described ways of influencing the uniform distribution the application weight over the web width is the comparatively high constructive and mechanical engineering effort as well as the lengthy due to the large number of control elements and less reproducible adjustment of the uniform distribution.

The construction of an automatic control loop for setting and maintaining an even distribution of the application weight is also known. Here, the coating weight is determined by, for example, beta emitters at as many measuring points as control elements while the coating is running and, in the event of deviations from the specified target value, a control signal is output to the respective element. Thermobolts and piezo elements are preferably used as control elements.
A disadvantage is the enormously high mechanical engineering, measurement and control technology as well as the financial outlay required for such a system.

Another known measure for equalizing the substance flow across the width is the integration of a feed pump extending over the entire length of the nozzle into the nozzle body itself. Gear pumps or rotary vane pumps are used here as feed pumps.
The disadvantage of this is the high mechanical engineering effort.

From certain points of view it makes sense that the coatings do not have closed surfaces, but are applied point-wise, what for example, allows the skin under bandages due to the possibility of leakage not macerated by sweat and other excretions of the skin. Adequate Rotary screen printing is a method to achieve this punctiform coating Further processes are the halftone printing and the inkjet principle.

In rotary screen printing, there is a nozzle inside a rotating screen, the fluid to be coated is introduced into the screen space from the outside and pressed through the screen holes in the direction of the substrate to be coated becomes. According to the transport speed of the substrate (rotation speed the sieve drum) the sieve is lifted off the substrate. Due to the adhesion and the internal cohesion of the fluid becomes that of the one already adhering to the carrier Based on the calottes, the limited supply of fluid in the holes is subtracted or promoted by the existing pressure on the carrier.

At the end of this transport, depending on the rheology of the fluid, the more or less strongly curved surface above the given base area the calotte. The ratio of the height to the base of the calotte depends on the ratio of the hole diameter the wall thickness of the sieve drum and the physical properties (flow behavior, Surface tension and wetting angle on the substrate) Fluids.

The implementation of the process is described fundamentally in CH 648 497 A5, improvements are described in EP 0 288 541 A1, EP 0 565 133 A1, EP 0 384 278 A1, DE 42 31 743 A1 and US 5,626,673.

The basic structure of pre-metering nozzles for rotary screen printing is similar to that of coating nozzles for full-surface coatings. In contrast to these, the installation space is very limited here, since the nozzle must find space inside the screen cylinder, which usually has a diameter of only a good 20 cm. Designs of the nozzle are also explained in the documents mentioned above. As a rule, there is an independent adjustment of the gap to the screen or to the counter-pressure roller on the left and right of each other. Since the sieve performs a certain re-dosing function and thus contributes to the homogenization of the application weight across the web width, there are generally no further adjusting elements for homogenization.
However, the avoidance of measures for homogenization in sieves with a large open area (> 30% permeability) becomes problematic, since the replenishment function becomes less and less effective here, especially when working with high fluid pressure.

Only in a few cases does the cross section of the outlet gap become section-wise adjustable or a dust bar inserted. So far, only adjusting screws uses what is a setting while screen printing is in progress makes impossible. Also described is the integration of one over the entire Gear pump extending nozzle length (EP 0 288 541 A1).

An important aspect that has not been taken into account in the design of screen printing nozzles is the deflection of the nozzle due to its own weight or due to desired measures.
The reason for disregarding the former is that the nozzle length has hitherto hardly been more than about 50 cm. However, if you run screen printing nozzles with a length of more than one meter, which due to the process are only stored at their ends, the deflection due to the low moment of inertia of this nozzle design can no longer be neglected. Even a difference in the gap to the counter-pressure roller of only 0.01 mm results in an application weight fluctuation of about 5 g / m ² for screens with a large open area (for example 50%).

The object of the invention is to provide a method that is excellent is suitable, viscous liquids with identical application quantity over the entire Apply width of the carrier material by means of a nozzle, the nozzle body bent and to avoid the disadvantages known from the prior art.

This problem is solved by a method as described in the main claim is. The subclaims relate to advantageous developments of the subject matter of the invention.

• quer zur Durchlaufrichtung des Trägermaterials der Düsenkörper durchgebogen wird und
• die Durchbiegung durch Temperaturdifferenzen im Düsenkörper induziert wird.

Accordingly, the invention relates to a method for applying liquid or pasty substances, in particular thermoplastics, to a carrier material, the substance being at least partially applied to the carrier material running along the nozzle by means of a nozzle, wherein

• transverse to the direction of flow of the carrier material, the nozzle body is bent and
• the deflection is induced by temperature differences in the nozzle body.

The solution according to the invention of a coating process and the corresponding one Designing a nozzle avoids the disadvantages and weaknesses mentioned above. A constant application of the substance across the entire width of the carrier material is guaranteed.

In a preferred embodiment, the cross section of the nozzle body is shown in two zones with different temperatures, which are arranged along its longitudinal axis, so that there is a simple line of curvature without turning points.

In a further advantageous embodiment, the Zones of different tempering in the longitudinal direction of the nozzle in at least three different tempered zones a bending line with at least one turning point generated.

The zones can be tempered by heating or cooling. Corresponding can be heat-carrying or cooling fluids that are in channels accordingly the zoning, or electrical heating elements are used. Peltier elements, radiation or convection heaters are also suitable.

In a special embodiment, the fluid to be coated itself is used as the temperature control medium used for at least one zone.

It is further preferred that the carrier material generates a back pressure Device, in particular a roller, is guided.

Applying the substance to the carrier material by means of the nozzle through a perforated cylinder (rotary screen printing process) is another excellent variant of the process.
It is particularly advantageous in this variant that the deflection of the nozzle can be adjusted by changing the temperature control even while a rotary screen printing operation is in progress, the nozzle being able to be made compact and the mechanical engineering outlay being comparatively low.

It can preferably both the deflection in the radial direction to the counter-pressure roller as well as the deflection perpendicular to it. In the first case it is direct Influence on the size of the gap between nozzle and counter-pressure roller, in in the second case, the gap remains constant in its vertical projection, the real gap dimension is influenced, however, by the fact that the nozzle lip is tangent to the counter-pressure roller is moved.

The method is also without the use of a device producing back pressure available; Here, the nozzle is bent perpendicular to the direction of the carrier material.

In a preferred embodiment, the nozzle is movable in its bearings and / or pivotable, ie to the right and left of the web independently of each other move or pivot.

Surprisingly, these few manipulated variables are sufficient to achieve an even one Bulk order to achieve the width of the coating web, many uniform distribution errors occur symmetrically, like the deflection of the nozzle due to its own weight, the crowning of the counter pressure roller due to thermal expansion or also flow-related effects due to non-optimal rheological interpretation of the Jet.

The construction of an automatic control loop for setting and Obtaining an even distribution of the application weight in the described method be solved. Here, with the coating in progress, the application weight is determined by Example beta emitters or infrared thermometers determined at only a few measuring points and in the event of deviations from the specified target value, an actuating signal to the corresponding one Output temperature control device.

With the described method, liquids with a dynamic Viscosity of 0.1 to 1000 Pas, preferably 1 to 500 Pas, are coated (measured at 175 ° C (DIN 53 018, Brookefield DV II, Sp 21)).

All inorganic and organic compounds are suitable as substances to be applied, their viscosity by increasing the temperature in the above range can be brought, also dispersions, emulsions, solutions and melts. For the coating of carrier materials with later medical, cosmetic or Adhesives are preferred for technical use, particularly preferred Self-adhesive compositions used. These preferably belong to the material classes of Solutions, dispersions, prepolymers and thermoplastic polymers.

Thermoplastic hot melt adhesives are advantageously used on Based on natural and synthetic rubbers and other synthetic polymers such as examples include acrylates, methacrylates, polyurethanes, polyolefins, polyvinyl derivatives, polyesters or silicones with appropriate additives such as fillers, adhesive resins, Plasticizers, stabilizers and other auxiliaries where necessary.

Your softening point should be higher than 50 ° C because the application temperature in the Usually is at least 60 ° C, preferably between 100 ° C and 180 ° C, respectively 180 ° C and 220 ° C for silicones. If necessary, post-cross-linking can be carried out UV or electron beam radiation may be appropriate to be particularly advantageous Adjust the properties of the hot melt adhesive.

In particular, hot melt adhesives based on block copolymers stand out through their diverse range of variations, because of the targeted lowering the glass transition temperature of the self-adhesive as a result of the selection of the tackifiers, the plasticizer as well as the polymer molecule size and the molecular weight distribution of the insert components becomes the necessary functional gluing with the skin also in critical areas of the human musculoskeletal system guaranteed.

The hot-melt adhesive is preferably based for particularly strongly adhesive systems on block copolymers, in particular A-B, A-B-A block copolymers or mixtures thereof. The hard phase A is primarily polystyrene or its derivatives, and the soft one Phase B contains ethylene, propylene, butylene, butadiene, isoprene or mixtures thereof, ethylene and butylene or mixtures thereof are particularly preferred.

Polystyrene blocks can also be contained in the soft phase B, to be precise at 20% by weight. However, the total styrene content should always be less than 35% by weight. Styrene contents between 5% and 30% are preferred, since a lower styrene content makes the adhesive more supple.

The targeted blending of di-block and tri-block copolymers is particularly advantageous a proportion of di-block copolymers of less than 80% by weight being preferred.

In an advantageous embodiment, the hot-melt adhesive has the following composition: 10% to 90% by weight block copolymers, 5% by weight to 80% by weight Tackifiers such as oils, waxes, resins and / or mixtures thereof, preferably mixtures of resins and oils, less than 60% by weight plasticizers, less than 15% by weight additives less than 5% by weight Stabilizers.

The aliphatic or aromatic oils, waxes and Resins are preferably hydrocarbon oils, waxes and resins, the oils such as Paraffinic hydrocarbon oils, or the waxes, such as paraffinic hydrocarbon waxes, have a beneficial effect on skin adhesion due to their consistency. Find as a plasticizer medium or long chain fatty acids and / or their esters. These additions serve to adjust the adhesive properties and stability. Possibly other stabilizers and other auxiliaries are used.

Filling the adhesive with mineral fillers, fibers, micro hollow or - solid bullets is possible.

Particularly high demands are made on medical carrier materials the adhesive properties. For an ideal application, the hot melt adhesive should have a high tack. The function-adapted adhesive force the skin and on the back of the carrier should be present. Furthermore, so it is too does not slip, a high shear strength of the hot melt adhesive is necessary. By specifically lowering the glass transition temperature of the adhesive due to the selection of tackifiers, plasticizers and polymer molecule size and the molecular distribution of the insert components becomes the necessary functional one Adhesion to the skin and the back of the carrier achieved. The height The shear strength of the adhesive is determined by the high cohesiveness of the block copolymer reached. The good grip is due to the range of resins used, Tackifiers and plasticizers.

The product properties such as stickiness, glass transition temperature and shear stability can be easily quantified with the help of dynamic mechanical frequency measurement. Here a shear stress controlled rheometer is used.
The results of this measurement method provide information about the physical properties of a substance by taking the viscoelastic component into account. Here, the hot-melt adhesive is set in motion at a predetermined temperature between two plane-parallel plates with variable frequencies and low deformation (linear viscoelastic range). The quotient (Q = tan δ) between the loss module (G "viscous part) and the storage module (G 'elastic part) is determined with computer-aided control. Q = tan δ = G "/ G '

A high frequency is used for the subjective feeling of tackiness (tack) chosen and a low frequency for the shear strength. A high numerical value means better tack and poor shear stability.

The glass transition temperature is the temperature at which amorphous or partially crystalline polymers change from the liquid or rubber-elastic state to the hard-elastic or glassy state or vice versa (Römpp Chemie-Lexikon, 9th edition, volume 2, page 1587, Georg Thieme Verlag Stuttgart - New York , 1990). It corresponds to the maximum of the temperature function at a given frequency.
A relatively low glass transition point is particularly necessary for medical applications. description T _G low frequency Cuddly low frequency / RT Touch sticky high frequency / RT Hot melt adhesive A -12 ± 2 ° C tan δ = 0.32 ± 0.03 tan δ = 1.84 ± 0.03 Hot melt adhesive B -9 ± 2 ° C tan δ = 0.22 ± 0.03 tan δ = 1.00 ± 0.03

The hot melt adhesives are preferably set so that they are at one frequency of 0.1 rad / s a dynamically complex glass transition temperature of less than 15 ° C, preferably from 5 ° C to -30 ° C, very particularly preferably from -3 ° C to -15 ° C, exhibit.

Hot melt adhesives in which the ratio is preferred according to the invention the viscous part to the elastic part at a frequency of 100 rad / s at 25 ° C is greater than 0.7, especially between 1.0 and 5.0, or hot melt adhesives which is the ratio of the viscous component to the elastic component at a frequency of 0.1 rad / s at 25 ° C is less than 0.6, preferably between 0.4 and 0.02, very particularly preferably between 0.35 and 0.1.

With partial coating, the domes or polygeometric Body shapes have different shapes. Flattened hemispheres are preferred. Furthermore, other shapes and patterns are also printed on the carrier material possible, for example a print image in the form of alphanumeric character combinations or patterns such as grids, stripes, as well as accumulations of the calottes and zigzag lines.

The adhesive can be evenly distributed on the backing material, but it can also functionally appropriate for the product over the surface of different thicknesses or densities be applied.

All rigid and elastic fabrics made of synthetic are suitable as carrier materials and natural raw materials. Carrier materials are preferred after application the adhesive can be used so that they meet technical requirements or fulfill the characteristics of a functional association. Are exemplary Textiles such as fabrics, knitted fabrics, scrims, fleeces, laminates, nets, foils, foams and Papers listed. These materials can also be pretreated or post-treated become. Common pretreatments are corona and hydrophobizing; common Post-treatments are calendering, tempering, laminating, punching and mounting.

Especially when directly coating the carrier material, this must have a certain Have strength and density to prevent the Dome penetrate too far into the carrier material or even penetrate.

In a preferred embodiment of the method according to the invention, the Calottes and / or polygeometric body shapes after coating on one second carrier material transferred. In this case, the second carrier material is the actual carrier, the first carrier material serves as an auxiliary carrier. Such an auxiliary can also be carried out in the form of an abhesively coated roller or webbing his.

A preferred embodiment of the auxiliary carrier is the roller with an abhesive surface. the abhesive surface of the roller can consist of silicone or fluorine-containing compounds or plasma-coated separation systems. These can be applied in the form of a coating with a basis weight of 0.001 g / m ² to 3000 g / m ² , preferably 100 to 2000 g / m ² .

To carry out the method, it is desirable that the adhesive surface the roller in its temperature between 0 ° C and 200 ° C, preferably less than 60 ° C, is particularly preferably adjustable below 25 ° C. It is particularly advantageous if the abhesive properties of the surface of the roller are matched so that the applied self-adhesive also adheres to a cooled roller (<25 ° C).

Subsequent calendering of the coated product and / or pretreatment of the carrier, such as corona radiation, for better anchoring of the adhesive layer can be beneficial.

Treatment of the hotmelt adhesive with electron beam postcrosslinking can also be used or UV radiation to improve the desired Lead adhesive properties.

The carrier material is preferably at a speed of greater than 2 m / min, preferably 20 to 200 m / min, coated.

The partial application enables the transepidermal to be removed through regulated channels Water loss and improves the evaporation of the skin when sweating in particular when using air and water vapor permeable carrier materials. This causes skin irritation caused by congestion of the body fluids are avoided. The created drainage channels allow drainage also using a multi-layer dressing.

Through the use of breathable coatings in connection with elastic, Breathable backing materials also result in a subjective result from the user pleasant perceived comfort.

In a preferred embodiment of the method according to the invention, the support material coated in this way has an air permeability of greater than 1 cm ³ / (cm ² * s), preferably 10 to 150 cm ³ / (cm ² * s), and / or a water vapor permeability of greater than 200 g / (m ² * 24h), preferably 500 to 5000 g / (m ² * 24h).

In a further preferred embodiment of the method according to the invention If the backing material coated on steel has an adhesive force on the back of the backing of at least 0.5 N / cm, especially an adhesive strength between 2 N / cm and 20 N / cm.

In a further advantageous embodiment, the self-adhesive compositions foamed before they are applied to the carrier material.

The self-adhesive compositions are preferred with inert gases such as nitrogen, carbon dioxide, Noble gases, hydrocarbons or air or their mixtures foamed. In some cases, foaming has additionally occurred due to thermal decomposition gas-evolving substances such as azo, carbonate and hydrazide compounds as proven suitable.

The degree of foaming, ie the gas content, should be at least about 5% by volume and can range up to about 85% by volume. In practice, values from 10% by volume to 75% by volume, preferably 50% by volume, have proven successful. If you work at relatively high temperatures of around 100 ° C and a comparatively high internal pressure, very open-pored adhesive foam layers are created, which are particularly well permeable to air and water vapor.
The advantageous properties of the foamed self-adhesive coatings such as low adhesive consumption, high tack and good conformability even on uneven surfaces due to the elasticity and plasticity as well as the initial tack can be optimally used particularly in the field of medical products.

A particularly suitable method for producing the foamed self-adhesive works according to the foam mix system. Here, the thermoplastic self-adhesive is reacted under high pressure at a temperature above the softening point with the gases provided, for example nitrogen, air or carbon dioxide, in different volume fractions (approximately 10% by volume to 80% by volume) in a stator / rotor system.
While the gas admission pressure is greater than 100 bar, the mixed pressures gas / thermoplastic in the system are 40 to 100 bar, preferably 40 to 70 bar. The PSA foam thus produced can then enter the coating nozzle via a line.

Due to the foaming of the self-adhesive and the resulting open Pores in the mass are those with the adhesive when using an inherently porous carrier coated products well permeable to water vapor and air. The needed The amount of adhesive is significantly reduced without impairing the adhesive properties. The adhesives have a surprisingly high tack (tack) there is more volume per gram of mass and therefore the adhesive surface for wetting the adhesive surface is available and the plasticity of the adhesive is increased by the foam structure. The anchoring on the carrier material is also thereby improved. In addition, the foamed adhesive coating gives, as already mentioned above, the products have a soft and cuddly feel.

Foaming also generally lowers the viscosity of the adhesive. This lowers the melting energy, and thermally unstable carrier materials can also be used be coated directly.

The outstanding properties of the self-adhesive finish according to the invention Backing materials put the use for medical products, in particular Plasters, medical fixations, wound coverings, doped systems, in particular for those that release substances, orthopedic or phlebological bandages and Tie close.

Finally, the backing material can be coated with an adhesive repellent after the coating process Backing material, such as siliconized paper, covered or with a Wound dressing or padding.

It is particularly advantageous if the carrier material can be sterilized, preferably gamma sterilized, is. Hot melt adhesives are particularly suitable for subsequent sterilization on a block copolymer basis, which do not contain double bonds. This applies in particular to styrene-butylene-ethylene-styrene block copolymers or Styrene-butylene-styrene block copolymers. There are no applications significant changes in the adhesive properties.

It is also ideal for technical reversible fixations, which are used in Peeling no injury or damage to various substrates, such as paper, Allow plastics, glass, textiles, wood, metals or minerals.

Finally, technically permanent bonds can be made, which only can be separated with partial splitting of the subsoil.

Based on some figures and an example, an advantageous embodiment of the Subject of the invention are shown without unnecessarily restricting the invention to want.

Figur 1

einen Ausschnitt aus einer Beschichtungseinheit, die nach dem erfindungsgemäßen Verfahren arbeitet, wobei die Düse radial zur Gegendruckwalze durchgebogen ist,

Figur 2

einen Querschnitt durch die Düse,

Figur 3

einen Ausschnitt aus einer Beschichtungseinheit, die nach dem erfindungsgemäßen Verfahren arbeitet, wobei die Düse senkrecht zum Radius der Gegendruckwalze durchgebogen ist,

Figur 4

einen Ausschnitt aus einer Beschichtungseinheit, die nach dem erfindungsgemäßen Verfahren arbeitet, wobei die Düse in mehreren Zonen entlang der Düsenlängsachse radial zur Gegendruckwalze durchgebogen ist, wobei sich eine Biegelinie mit zwei Wendepunkten ergibt.

Show it

Figure 1

a section of a coating unit which works according to the method according to the invention, the nozzle being bent radially to the counter-pressure roller,

Figure 2

a cross section through the nozzle,

Figure 3

a section of a coating unit that works according to the inventive method, the nozzle being bent perpendicular to the radius of the counter-pressure roller,

Figure 4

a section of a coating unit that works according to the inventive method, wherein the nozzle is bent radially to the counter-pressure roller in several zones along the longitudinal axis of the nozzle, resulting in a bending line with two turning points.

Figure 1 shows a section of a coating unit, according to the invention Process works, the nozzle 1 being bent radially to the counter-pressure roller 6 is. The temperature in the heated by the temperature control elements 3 Zone of the nozzle body higher than in the zone heated by the temperature control elements 4. Section A-A shows the position of the exit gap 5.

Figure 2 shows a cross section. The carrier material 7 is in a gap between the Nozzle 1 and the counter-pressure roller 6 (direction of rotation 8) out. Through the exit gap 5 the nozzle, the carrier material 7 is coated with a fluid. The fluid flows through a distribution pipe 2 lying axially in the nozzle base body 1 via the outlet gap 5 to the coating point.

The nozzle body is heated by temperature control elements 3 and 4, which are used in the manufacture the deflection different temperature levels in the lower and upper Generate nozzle body.

Figure 3 shows a section of a coating unit, which according to the invention Process works, the nozzle 1 perpendicular to the radius of the counter-pressure roller is bent. The temperature in the temperature control element 3 is heated zone of the nozzle body higher than in that by the temperature control elements 4th heated zone. Section A-A shows the position of the exit gap 5.

Figure 4 shows a section of a coating unit, which according to the invention Process works, the nozzle in several zones along the longitudinal axis of the nozzle is bent radially to the counter-pressure roller. It is in zone 1 and zone 3 the temperature in the lower area of the nozzle body is higher than in the upper area while in zone 2 the temperature in the upper area is higher than in the lower area. The result is a bending line with two turning points.

Example:

In a rotary screen printing machine of 1m coating width, which with the usual Devices for guiding an endless web such as unwinding, reeling, web edge control and web tension measuring systems and their coating part from a rotating circular sieve, one in the 12 o'clock position relative to the sieve

• Verarbeitungstemperatur in Zuführsystem und Düse 120 °C
• Verarbeitungstemperatur im Bereich Sieblöcher 120 °C
• Flächengewicht der Papierbahn 65 g/qm
• Sieb 14 mesh, Lochgröße 0.9 mm

A nozzle and a counter pressure roller, with which the screen is pressed against the coating nozzle, are coated with a thermoplastic adhesive on a paper web.

• Processing temperature in feed system and nozzle 120 ° C
• Processing temperature in the area of screen holes 120 ° C
• Basis weight of the paper web 65 g / sqm
• Sieve 14 mesh, hole size 0.9 mm

• 2 Elektroheizstäbe im Düsengrundkörper oberhalb des zentralen Verteilrohres Leistung: 12 kW
• 2 Elektroheizstäbe im Düsengrundkörper unterhalb des zentralen Verteilrohres Leistung: 12 kW
• Die oberen und unteren Elektroheizstäbe können in ihrer Temperatur unterschiedlich eingestellt werden.

The nozzle heating is carried out as follows:

• 2 electric heating elements in the nozzle body above the central distribution pipe. Power: 12 kW
• 2 electric heating elements in the nozzle body below the central distribution pipe. Power: 12 kW
• The temperature of the upper and lower electric heating elements can be set differently.

The nozzle is mounted on the side on swivel arms that run against stops by means of which the distance between the nozzle and the counter-pressure roller and screen right and left can be set independently.

The outlet gap of the nozzle has a constant width.

The counter pressure roller is not actively tempered.

With this device, an application weight of 130 g / qm could be achieved. To even out the application of mass across the web, the lower nozzle heater was set 15 ° C higher than the upper nozzle heater. The standard deviation of the mass application across the web was then 1.7 g / m ² .

Claims (12)

Method for applying liquid or pasty substances, in particular thermoplastics, to a carrier material, the substance being at least partially applied to the carrier material running along the nozzle by means of a nozzle, characterized in that transverse to the direction of the carrier material, the nozzle body is bent and the deflection is induced by temperature differences in the nozzle body. Method according to claim 1, characterized in that the nozzle has at least two differently tempered zones in its cross section and / or along its longitudinal axis. Process according to claims 1 and 2, characterized in that a heat-carrying or cooling fluid, electrical heaters, Peltier elements, radiation or convection is used to temper the nozzle body. Process according to claims 1 to 3, characterized in that the coating liquid itself is used for tempering at least one of the zones. Method according to claims 1 to 4, characterized in that the nozzle is movable and / or pivotable in its bearings. Process according to claims 1 to 5, characterized in that the deflection takes place essentially perpendicular to the carrier material or essentially in or against the running direction of the carrier material. Method according to claims 1 to 6, characterized in that the carrier material is guided along a device generating counter pressure, in particular a roller. Method according to one or more of the preceding claims, characterized in that the substance is applied to the carrier material by means of the nozzle through a perforated cylinder. Method according to one or more of the preceding claims, characterized in that the deflection of the nozzle is regulated as a function of the quantity of substance applied on the running web. Method according to one or more of the preceding claims, characterized in that the substance has a dynamic zero viscosity of 0.1 Pas to 1000 Pas, preferably from 1 Pas to 500 Pas, at the processing temperature. Method according to one or more of the preceding claims, characterized in that the substance is a solution, a dispersion, a prepolymer or a thermoplastic polymer, is preferably a hot melt adhesive, particularly preferably a hot melt pressure sensitive adhesive. Method according to one or more of the preceding claims, characterized in that the carrier material is a roller or a belt webbing with an abhesive surface, the abhesive surface consisting in particular of a coating of compounds containing silicone or fluorine or plasma-coated separation systems, which have a very particular basis weight from 0.001 g / m ² to 3000 g / m ^{2 is} applied, preferably 100 to 2000 g / m ² .

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