WO2013110992A1 - Method for producing a wood-material moulding - Google Patents

Abstract

The invention relates to a method for producing a wood-material moulding using a wood base material and a thermally curable binder by pressing, wherein a heat transfer into the wood-material moulding takes place in the form of a surge of steam to cure the binder. In order to reduce the pressing time, it is proposed to increase the process air pressure, prevailing in the pressing chamber before the heat transfer in the form of a surge of steam, with respect to the atmospheric air pressure prevailing outside the pressing chamber. By relieving the pressure in a specific way during the pressing time, the material is abruptly heated through, allowing the timing and execution of the heating-through process to be influenced.

Description

 description

 Process for producing a wood-based molded part

The invention relates to a method for producing a wood material molding using a

Wood material base material and a thermosetting binder by pressing, wherein the curing of the

 Bindemittels a heat transfer into the wood material molding in the form of a DampfStoßes occurs.

Such methods are known in the art. The duration of the pressing time is primarily influenced by how fast the binder hardens

Example of a three-layer wood-based panel, which consists of a middle layer, an upper and a lower cover layer, the solutions known from the prior art are described below.

To produce the plate, a three-layer constructed wood material mat (fleece), consisting of the wood material base material and a thermosetting binder, fed to a press. Subsequently, a Heißpreßvorgang takes place. The curing of the binder (glue) in the outer cover layers by direct heat through heated press plates or bands. Due to the heat energy introduced into the plate on the one hand and the moisture in the plate on the other hand, a water vapor pressure gradient is formed in the plate.

The heat energy required for curing the middle layer is in the plate via the so-called steam pulse

brought in. For this purpose, the outer press plates are heated, for example, to 0 ° Celsius. When pressing the water (glue water) is then heated in the outer layers and transferred when the boiling point (100 ° C), suddenly in the vapor phase. This steam shoots vertically from both sides of the plate towards the center of the plate due to the water vapor pressure drop. This process is called steam shock.

Due to the temperature gradient between the outer sides of the outer layers and the middle of the middle layer (the temperature difference is for example 75 ° C), the vapor condenses in the still cool middle layer. It releases heat of condensation, which raises the temperature in the middle layer. The chemical curing reactions in the middle layer are faster and it takes less time for the binder to harden, resulting in a shorter press time. This steam jet principle is used in the production of numerous wood-based molded parts, for example in the production of chipboard, MDF, OSB, etc.

From the prior art, it is known to optimize the steam pulse principle in that the water vapor is previously heated and injected as superheated steam under pressure in the wood material molding. This is also referred to as steam injection technology. As a result, a shortening of the pressing time is possible to a limited extent.

However, it is disadvantageous that in the steam injection technique more water also gets into the interior of the wood-based molded part. Because of the basic principle of

Pressure and back pressure is greatly increased in the steam injection technique, the internal pressure in the wood-based molding. When the press opens, the binder must already be cured inside the molding so far that the internal vapor pressure does not lead to damage (spalling of parts) or destruction of the molding (delamination). It is attempted to counter this disadvantage with expensive cooling devices for cooling the moldings after hot pressing. Nevertheless, the press must remain closed comparatively long in the steam injection technique, so that the time advantage of the rapid curing of the binder is partially canceled.

In DE 1 2008 026 258 it has been proposed to allow the burst of steam to take place under elevated pressure. The process described therein is characterized in that prior to the heat transfer in the form of a steam surge prevailing in the press room process air pressure is increased relative to the prevailing outside the baling chamber atmospheric air pressure, but without the wood material molding moisture, especially in the form of water vapor to feed. A provided for the production of such a wood-based molded part press is characterized by a compression chamber and a device for generating an overpressure such that are increased before the heat transfer in the form of a burst of steam prevailing in the press room process air pressure relative to the prevailing outside of the baling chamber atmospheric air pressure can, without however beyond the Holzwerkstoff- molded part moisture, especially in the form of water vapor, supply.

By applying and maintaining an external overpressure during the pressing process, DE 1 2008 026 258 achieves that the boiling point of the water is increased beyond 10 ° C. This has the consequence that with a shot of steam at e.g. 1 ° C significantly more heat energy can be introduced into the middle layer of the wood-based molding. This increased amount of heat that is released in the condensation of the water vapor in the still cold middle layer leads to a much higher temperature in the middle layer compared to the conventional steam injection technique, with the result that the curing reactions of the glue run much faster. In summary, with the technique described in DE 1 2008 026 258, the steam blast takes place at a higher temperature, which leads to a shortening of the pressing time.

An object of the present invention is to provide a technique for producing a wood-based molded article with the aid of which the pressing time can be shortened even further.

This object is achieved by a method according to claim 1 or by a press according to claim 5. Advantageous embodiments of the invention are specified in the subclaims.

The advantages and embodiments explained below in connection with the method also apply mutatis mutandis to the devices according to the invention and vice versa.

The core of the present invention is that during pressing a targeted reduction of the process air pressure to initiate the DampfStoßes occurs. For this purpose is a

Press according to the invention provided with a pressure relief device, so that during the pressing of the process air pressure targeted, even alternately lowered. By a targeted pressure relief during the pressing a sudden heating of the material, whereby timing and flow of the heating can be influenced.

The present invention is based on the basic findings described in DE 1 2008 026 258, as described below:

Thereafter, leading to a technological dead end steam injection technique in which hot steam is pressed under pressure into the molding, no longer pursued. Instead, there is a return to the original steam shock technique, in which the steam pulse is automatically on reaching the boiling point. This steam shock technique is improved in DE 1 2008 026 258 in that during the pressing process, at least in the baling chamber of the press, the air pressure is greater than the atmospheric pressure of the environment. In other words, the pressing process takes place under overpressure, e.g. at 1.5 bar. At such an overpressure, the water evaporates at higher temperatures, for example at 11 ° C. The shot of steam is still automatic, but this time at a higher temperature. In comparison with a running under atmospheric pressure process, the shot of steam may take place at a somewhat later date, but with a correspondingly higher energy content corresponding to the higher boiling temperature.

The invention described in DE 1 2008 026 258 makes the dependence on boiling temperature and boiling pressure

benefit from each other. By increasing the pressure, for example, 0.5 bar = 500 hPa, an increase in the boiling point of the water from 10 ° C to about 11 ° C is reached. This increases the energy content of the water vapor compared to a process occurring at atmospheric pressure. When using the same amount of water, more heat can be transferred to the interior of the wood-based molding using the steam blast. This increases the achievable temperature in the middle class. According to the van 't-Hoffsehen rule (RGT rule), according to which the reaction rate is approximately doubled when the temperature is increased by 1 ° C, thus resulting in a significantly increased reaction rate for the chemical

Curing reactions of the binder. As a result, the pressing time can be significantly shortened, the risk of delamination is no longer present, since no additional water vapor is introduced into the molded part.

 In contrast to the original steam injection technique, in which the heat energy introduced into the wood-based material molding is substantially increased by increasing the amount of water vapor used, the invention described in DE 1 2008 026 258 is based on the consideration of the reaction rate Increase the curing reactions of the binder in that with an equal amount of water vapor we transfer more heat energy. This allows a high process temperature can be achieved without the disadvantages of increased internal pressure.

The resulting water vapor is the moisture content of the air, the

provided that no dry peephole is used as a process atmosphere - already contained in the air anyway,

as well as the water vapor, which has its origin in the glue water of the cover layers.

The following presentation should once again clarify the difference between the known steam injection technique and the invention described in DE 1 2008 026 258:

In the conventional Dampfin ektionstechnik the partial pressure conditions result from a combination of (humid) air on the one hand and additionally introduced into the system superheated steam on the other hand:

P (total) = p (air) + p (Was9er)

Upon reaching the boiling temperature of 10 ° C, the steam obtained from the water contained in the moist air and water vapor from the water vapor, which ^has its origin in the stick water of the cover layers' as well as the additionally introduced superheated steam.

In the invention described in DE 1 2008 026 258, the introduction of superheated steam is dispensed with. In the pressure chamber is only the usual process atmosphere, usually air in the usual composition (78% nitrogen, 21% oxygen, ...). It follows:

 P total = P (air)

The burst of steam that results when reaching the (elevated) boiling point, for example, 11 ° C, contains significantly less moisture and at the same time a higher heat energy, which leads to the advantages described above.

Since the pressing process takes place under overpressure, a pressure chamber is provided in which the desired overpressure prevails. Under the atmospheric air pressure is then the pressure prevailing outside the pressure chamber in the atmosphere, caused by the weight of the air pressure to understand Under process air pressure, however, is the air pressure of the environment in which the pressing takes place. Since the pressing always takes place in a compression space, for example in the press nip arranged between press plates or belts, the process air pressure is in other words the (at least) prevailing in the compression chamber air pressure to which the wood-based molded part to be produced is exposed. In one embodiment of the invention described in DE 1 2008 026 258, the press room, in particular in the form of the press nip, is designed to achieve the desired overpressure as a substantially closed pressure chamber. In another embodiment of the invention described in DE 1 2008 026 25 8 a Druckkammer- is provided which surrounds other parts of the press in addition to the actual pressing chamber. In a further embodiment of the invention described in DE 1 2008 026 258, the press has a pressure chamber completely surrounding it; the entire press is then inside the pressure chamber.

The press described in DE 1 2008 026 258 has suitable technical facilities for this purpose, which are familiar to the person skilled in the art and therefore need not be listed here in detail. For example, if the press nip formed as a pressure chamber, so devices for sealing the press nip are provided, for example, laterally mounted sealing rings, pressure devices, etc. In discontinuously operating presses, for example

discontinuously operating single or multi-day presses, it is possible to provide lateral sealing surfaces which seal all four sides when closing the press. In addition to the structural elements and seals for delimiting the pressure chamber, a device for generating an overpressure is to be provided. It may be an overpressure container that provides an overpressure of, for example, 0.5 to 1 bar. For this an overpressure can be fed into the pressure chamber via pressure lines. Thus, the boiling point of the water may be at e.g. 11 ° C to 0 ° C are set.

In addition to the above findings, as described in DE 1 2008 026 258, the present invention is based on the following considerations:

While in the original steam shock method, the steam shot was always spontaneous and also in the technique described in DE 1 2008 026 25 8 a spontaneous steam pulse is caused, the present invention proposes to maintain the principle of steam blast under increased pressure, but the time of To influence steam. In other words, there is no spontaneous burst of steam anymore. Instead, the timing of the steam blast is controlled specifically. The steam burst is in other words initiated. In the following, therefore, is also spoken by a "forced steam blast." In other words, by a skillful control of the pressure gradients during the pressing operation a steam ewegung (steam shot) forced within the mat.

A basic idea of the present invention thus lies in an additional relief step, namely one

targeted lowering of the previously established process air pressure during pressing. In other words, there is a pressure relief before the end of the pressing time, this pressure relief takes place, depending on the application, either partially or completely. In other words, even after the pressure relief, an increased process air pressure may be present or else the process air pressure corresponds again to the atmospheric air pressure prevailing outside the compression space.

This targeted pressure reduction extremely rapid temperature increases are achieved in the fleece. The internal temperature is rising not only very fast, but also to values _{above l} o _r legally not be reached. This is a significantly increased energy content. In other words, more energy can be introduced into the middle layer of the mat, there is a sudden heating of the material, combined with a high energy input, resulting in a significant reduction in the pressing times.

This principle will be explained in more detail below. In the method according to the invention, the water located on the surface of the mat is prevented from boiling by the increased pressure. As a result, temperatures of well over 10 ° C can be achieved at this point. By deliberately lowering the process air pressure, there is an abrupt increase in the internal temperature of the mat, which is caused by the sudden formation of steam due to the pressure relief. As is known with the steam pulse principle, here too the water vapor can spread exclusively in the direction of the center of the mat, which leads to very high temperature increases. This can be compared to all other known from the prior art steam pulse Techniques to measure much larger temperature increases in a very short time. Thus, for example, in the case of a nonwoven in which a pressure relief was carried out after about 3 minutes press time, an increase in the internal temperature of 70 ° C by 47 ° K to 117 ° C within 1 second after the pressure relief.

A significant advantage of the present invention is that by deliberately forcing the steam blast the time of DampfStoßes, d. 11. The time at which the energy is sent to the middle layer of the mat can be optimally selected. As a result, this leads to a further shortening of the pressing time.

Optimum timing of the burst of steam means that the time of depressurization is chosen so that the remaining time left by the web in the press is just enough to cure the wood-base molding, i. to stabilize the chemical bonds at least so far that the wood-base molding does not burst (delaminate) when the press is opened.

At the same time, forcing the steam pulse through an influenceable pressure relief means that the strength of the steam pulse can be influenced in a targeted manner. In other words, the manner in which the depressurization is carried out can influence the speed with which the steam jet flows in the direction of the middle layer. This can be regulated by a defined lowering of the process pressure. If, for example, the process air pressure is spontaneously reduced to 1 bar, the steam pulse will be vehement. If the pressure is reduced within a period of, for example, a few seconds, this is due to the structure of the

Molding gentle. Too rapid pressure relief, which could possibly lead to damage to the structure of the wood matrix, is thus avoided. With other locations, a delayed lowering of the process air pressure can protect the structure of the wood-based material molding to be produced. Therefore, it is advantageous if a pressure control is provided by means of which the sealing device can be influenced so that the pressure in the press room can be selectively changed.

But also an accelerated lowering of the process air pressure by an additional application of vacuum and thus increasing the pressure gradient is possible and may be useful in certain applications. For example, to increase the pressure difference, it would be conceivable to apply an overpressure on the press mouth and a vacuum on the press outlet. By applying a negative pressure of the water vapor from the wood-based molded part is then sucked out formally.

In the previously known methods had to be expected with more or less long process times that were difficult to influence. A control or regulation of the process was not or only partially possible. With the present invention, extended process control and control is possible. While in the known from the prior art method as the only parameter of the process air pressure was variable in the present invention in addition to this process air pressure in addition, the time of pressure reduction (pressure relief) and the speed of pressure reduction can be influenced. As a result, it is possible in an advantageous manner to influence the material structure of the wood-base molded parts produced and thus, above all, their strength properties.

Like the process described in DE 1 2008 026 258, it is not provided in the present invention to supply moisture to the wood-based molded part during pressing, in particular in the form of water vapor. The moisture required for the steam pulse is already contained in the wood-based mat. However, an amount of moisture may be added to the molded article prior to the pressing operation, preferably by spraying or otherwise spreading onto the nonwoven fabric. The amount of sprayed water, depending on the material, for example, 1 to 2 g per side and millimeter plate thickness. By introducing this additional moisture, the subsequent burst of steam is enhanced.

Like the method described in DE 1 2008 026 258, the present method can also be used in the production of numerous wood-based molded parts, for example in the production of chipboard, MDF, HDF, OSB, etc. The wood-based molded parts may be Single parts or to act continuously running through the press Endlosteil. The method can be used both on discontinuous, as well as on continuously operating presses, for example on single or multi-day presses, double belt presses, etc.

Depending on which type of wood-based molded parts is to be produced, it is in the

Wood material base material around chips, fibers, stalls, etc. For example, urea, melamine or phenolic resins or mixtures thereof or mixtures of these resins with polymeric diisocyanates (PMDI) are known as thermosetting binders.

or with natural binders, such as tannin and / or lignin resins are used.

Embodiments of the invention are explained below with reference to the drawings. Show here

1 shows a representation of the present invention with reference to a discontinuous one-day press,

Fig. 2 is an illustration of the present invention based on a continuously operating press.

All figures show the invention only schematically and with its essential components. The same reference numerals correspond to elements of the same or comparable function.

In the production of a chipboard 3, wood, wood residues, wood moldings, etc. are first machined in a first process step, i. it is by suitable

Crushing process using

Messerringzerspanern, Langholzzerspanern etc. manufactured the desired optimum chip form. In a second process step, the chips thus produced are dried until final moisture in the range of 0.5 - 2% are reached. Subsequently, the chips are fractionated, ie divided into sieve fractions. Thereafter, the separate gluing of the so-called. Cover and middle layer chips with thermosetting resins, especially urea, melamine or phenolic resins or mixtures thereof or with polymeric diisocyanates (PMDI) or with natural binders such as tannin and / or lignin. After cutting, drying

and gluing is carried out as a fourth method step, the scattering of the glued chips by means of wind or throw scattering, by which a so-called "chip mat" 4 or a "chipboard" is generated. Viewed over the fleece height, the smaller and finer cover shavings are arranged at the top and bottom, while the coarser middle shavings are predominantly found in the center of the chip mat 4. In this arrangement, the glued chip mat

4 now fed to a press 1, in which by simultaneous action of heat and pressure compressing the chip mat 4 to the final desired

Chipboard thickness occurs with simultaneous curing of the thermosetting binder. In Fig: 1, a discontinuous Einetagenpresse 1 is shown by way of example, the press plates 2 has.

The chemical reactivities of the binders used in the top and middle layer (UF, MF, PF, MUF, PMDI, etc.) must be matched to the requirements of the compression reactions. Conversely, the moisture balance of the chipboard just emerging must be sized so that an optimal curing reaction in the top and middle layer can be done and the chipboard 3 is not in the moment when they leave the press 1 and the external pressing pressure thus eliminated, by too high delaminated internal vapor pressure, ie bursts. The duration of the pressing time is primarily influenced by how fast the binder hardens.

The chip mat 4 is fed to the press 1, whose press nip

5 is designed as a pressure chamber. The press nip 5 is connected via pressure lines 6 with a pressure vessel 7, with the help of the introduction of the chip mat 4 and the

Closing of the press nip 5 by suitable seals (not shown), an overpressure of 0.5 bar in the press nip 5 is generated. Moisture, in particular in the form of water vapor, is not supplied to the press nip 50 or the chip mat 4. By increasing the process air pressure, there is an increase in the boiling temperature within the nip 5. The water vapor produced at 11 ° C carries a much higher energy content, with the result that with the shot of steam also significantly more condensation heat in the middle layer the chip mat 4 arrives. This in turn means that the curing reactions of the binder in the middle layer proceed much faster. Thus, a sufficient strength is achieved significantly faster in the middle layer.

Thus, the pressing time can be significantly shortened or the feed rate of the press 1 can be significantly increased without the risk that the particle board 3 delaminated when extending from the press 1. The burst of steam is not spontaneous, but is initiated by the fact that a pressure relief valve 8 is opened before the end of the pressing time.

Another embodiment will be described with reference to FIG. When the press is a continuous (floor) press 1 with a rotating press belt 12, comprising a top and a bottom band. The press width is for example 2.20 m.

If the large-volume fleece in the form of a first example, 0 to 120 mm thick chip mat 4 of the press 10 is supplied, takes place during the so-called "pre-pressing" initially a compression. The mat 4 is doing by the press mouth to its final thickness of For example, 22 mm compressed. The Preßbackentemperatur during the "pre-pressing" is for example 250 ° C. After a preheating of 80 seconds, for example, the temperature of the water in the cover layers of the mat 4 after the "pre-pressing" 70 to 80 ° C. Subsequently, the press 10 The press nip 5 in turn serves as a pressure chamber.

To seal the press 10, only the press mouth and the press nip 5 must be sealed. A seal of the entire press 10 is not required. The press nip 5 can be sealed by means of a simple pressure seal or pressure seal. For this purpose, there is a lateral sealing of the press nip 5 by laterally mounted on both sides of the press 10 sealing devices. The design effort is reduced if each side of the press 10 is assigned a separate sealing device.

Such a sealing device is, for example, a circumferential, segmented pressure chain 19 or a circulating pressure band which seals one side of the press 10. Such a print chain 19 consists of juxtaposed links. The print chain 19 or the print tape sets in both the upper band, as well as on the lower band and presses between the bands against the lateral narrow surfaces of the mat 4. The print chain 19 and the print tape consists for example of a temperature-stable hard rubber material.

In a particular embodiment of the invention, the compression of the mat 4 already effected by the "prepressing" is used. It may even be necessary while

the "prepressing" or subsequently and before the application of a sealing device to vent air from the compression chamber to prevent excessive pressure increase.

But carried the seal of the press nip 5 usually only after _t pre-pressing ", ie after the mat 4 has reached its final thickness, or immediately following it. Only at this position corresponding to the press 10 enters the sealing device in operation, ie, for example, the This position is usually relatively far forward, ie the pressure chain 19 starts as possible starting with the press mouth The seal towards the press mouth is preferably carried out without further design effort, solely on the basis of existence the there located, already pressed, or just fed mat 4th

The sealing devices 19 extend on both sides of the press 10 in the direction of the press exit. However, they do not reach the end of the press 10, but end before. This determines the time of the pressure release.

During the pressing time in which the pressure chain 19 seals the press nip 5, there is a controlled increase in temperature and pressure up to the desired target values, or these values have already been reached and are only kept constant. Before the expiration of the pressing time then takes place a discharge of the pressure built up. For this purpose, one opens the side surfaces of the mat 4 by the print chain 19 is removed. This is advantageously targeted, gradually and accomplished with the aid of a corresponding pressure control. Then it finds more or less abruptly

the desired steam burst instead. More precisely, at a process air pressure of, for example, 3 bar, a temperature of, for example, 115 ° C. to 123 ° C. results in the cover layer of the mat 4. According to the invention, relief (relaxation) takes place because the pressure chain 19 is no longer on the sides the press 10 is applied, then air can escape from the porous middle layer to the outside. With the pressure relief, the water evaporates from the cover layers of the mat 4. It suddenly creates a lot of hydrogen, which moves into the middle layer ("forced steam burst"). Once in the middle class, the steam condenses again. As a result, so much heat is introduced into the middle layer, that there the temperature (internal plate temperature) increases very quickly. It comes to a sudden soaking the mat 4. This leads to a much faster compared to the _b is _h eri _g s technology curing. Chemical reactions are faster. This shortens the pressing times. Depending on the version, the speed of the press can be increased by 15% or more.

It may be provided initially to operate the press 10 normally until the desired feed rate is reached, z. B. 4 seconds per millimeter plate thickness. If this is the case, the seal according to the invention, for example in the form of the pressure chains 19, "switched" using the appropriate pressure control. The exact positions at which the print chains 19 are applied or removed may vary depending on the press equipment and operating conditions. Preferably, the press 10 is designed such that a variable positioning of the sealing device is possible. Is the sealing device

On, the feed rate can be increased, for example, to 3 seconds per millimeter plate thickness. In order to achieve the described functionality, it is preferably provided to form the print chain 19 in a segmented manner. This segmentation of the print chain 19 is therefore advantageously not only designed so that it allows a deflection of the print chain and thus a comparatively simple handling. Rather, a corresponding design of the pressure chain 19 also allows a locally variable application and lifting of the chain. In other words, the sealing device is preferably designed such that both the point on the side of the press 10, on which the sealing device is applied, a seal thus begins, as well as the point at which the sealing device is removed again, thus canceling the sealing is variable, in particular, is freely selectable.

All features described in the description, the figure and the following claims may be essential to the invention both individually and in any combination with one another.

LIST OF REFERENCE NUMBERS

1 press

 2 press plate

 3 chipboard

 4 chip mat

 5 press nip

 6 pressure line

 7 pressure vessel

8 pressure relief valve

Press press belt pressure chain

Claims

claims

 1. A method for pressing a wood-based material and a thermosetting binder in a pressing area during a predetermined pressing time to a wood material molding (3), wherein the curing of the binder, a heat transfer into the wood-based molding in the form of a shot of steam and wherein before the heat transfer in Form of DampfStoßes in the pressing area (5) prevailing process air pressure relative to the outside of the pressing area (5) prevailing atmospheric air pressure is increased, but without the wood material molding moisture, especially in the form of water vapor supply, characterized in that the heat transfer to takes place at the beginning of the pressing and in the pressing area and that the process air pressure in the pressing area at least until after the beginning of pressing increased maintained and only then, but before the end of the pressing time controlled in the pressing area is lowered.

2. The method according to claim 1, characterized in that before the end of the pressing time, a partial pressure relief takes place.

3. The method according to claim 1, characterized in that before the end of the pressing time a complete pressure relief takes place. Method according to one of claims 1 to 3, characterized in that the process air pressure is at least 0.5 bar above the atmospheric air pressure.

4. Press (1, 10) for the production of a wood material molding (3) using a wood-based material and a thermosetting binder, wherein for curing of the binder, a heat transfer into the wood material molding in the form of a steam blast, wherein the Einetagenpresse (1 ) a pressing space (5), the continuous press (1) a pressing area (5) and a device (6, 7) for generating an overpressure such that before the heat transfer in the form of a DampfStoßes prevailing in the pressing chamber (5) process air pressure relative to the outside of the baling chamber (5) prevailing atmospheric air pressure can be increased, characterized in that by means of a

Pressure relief device (8, 19) during the pressing of the process air pressure is selectively lowered.

 6. Press (1, 10) according to claim 5, characterized in that the pressing chamber (5), in particular in the form of a press nip, is designed as a substantially closed pressure chamber.

 7. Press (1, 10) according to claim 5 or 6, characterized in that at least one sealing device (19) seals the press nip (5) on both sides over a partial length of the press (10).

 8. Press (1, 10) according to any one of claims 5 to 7, characterized by a with the sealing device (19) connected and the function of the sealing device (19) influenced pressure control.