DE102019114021B3 - Method and device for preheating a pressed material mat - Google Patents

Abstract

The invention relates to a method for preheating a pressed material mat (2) before it enters a press (4), in particular during the production of wood-based panels, the pressed material mat (2) permitting a double-belt preheating device (3) with an upper, endless, gas-permeable Conveyor belt (5a) and a lower, endlessly circulating gas-permeable conveyor belt (5b) passes through, wherein the pressed material mat (2) is acted upon by a heated fluid which contains steam and is thereby heated. The method is characterized in that the pressed material mat (2) in the double-belt preheating device (3) is initially acted upon in a first stage with a first heating unit (7) with a steam-air mixture with a set dew point, which the mat from flows through one surface to the opposite surface and is thereby heated to a temperature (T1) over the entire mat thickness and that the pressed material mat (2) in the double belt preheating device (3) then in a second stage with a second heating unit (9) on both sides with steam or with a steam-air mixture is applied and thereby only the surface layers near the surface are heated to a second temperature (T2) which is higher than the first temperature (T1).

Description

The invention relates to a method for preheating a pressed material mat before it enters a press, in particular during the production of wood-based panels,
wherein the press mat passes through a double-belt preheating device with an upper, continuously circulating, gas-permeable conveyor belt and a lower, continuously circulating, gas-permeable conveyor belt,
wherein the press mat (in the double belt preheating device) is acted upon with a heated fluid which contains steam and is thereby heated,
wherein the pressed material mat in the double belt preheating device is initially acted upon in a first stage with a first heating unit with a steam-air mixture and
wherein the pressed material mat in the double belt preheating device is then acted upon in a second stage with a second heating device with steam or with a steam-air mixture.
The invention also relates to a double-belt preheating device for heating a pressed material mat and a system for producing wood-based panels.

The pressed material mat to be heated (which is also simply referred to as “mat”) is preferably a pressed material mat for the production of wood-based panels. In principle, however, the heating of other pressed material mats or material webs is also recorded. A pressed material mat for the production of wood-based panels usually consists of chips or fibers, in particular wood chips or wood fibers, preferably glued wood chips or wood fibers which, for. B. be sprinkled on a scatter belt conveyor or the like to a press mat. As a result, a continuous pressed material mat and consequently a pressed material mat strand is generated, which passes through a double belt preheater for heating and then in a press, for. B. in a continuously operating double belt press, using pressure and heat to form a plate or a plate strand.

In the production of wood-based panels, efforts are made to manufacture a product with the desired panel properties as economically as possible. A particularly important property of a wood-based panel is the sealing profile over the panel thickness, which can be influenced in the desired direction during panel production in the press by setting the heating plate temperatures, the pressing pressures and the setting of the press gap. The relevant settings of the hot press, e.g. B. a continuously operating double belt press, are referred to as a press program. To z. For example, to increase the flexural rigidity of a plate, the press program of the continuous press can be adapted so that higher densities are achieved in the area of the cover layers. On the other hand, in order to increase the transverse tensile strength of a panel, the press program of the continuous press can be adjusted so that a higher density is achieved in the center of the panel. Overall, the aim in panel production is to achieve the desired and previously specified panel properties or to keep them above the limit value and at the same time to reduce production costs, in particular by saving wood and glue. Furthermore, the production costs can be reduced by a simultaneous maximization of the production capacity. Various production parameters such as the amount of glue, the mat moisture and the pressing program (to optimize the shape of the density profile) are optimized. These measures relate to the operation of the press, in which the mat to be pressed is pressed into a plate using pressure and heat in a specific pressing program.

In order to optimize the production process, the mat of material to be pressed is preheated in a preheating device before the actual pressing process. To z. B. to increase the production capacity, are in the production, z. B. used in MDF production, preheaters in which the pressed material mat z. B. acted upon with a heated fluid (steam or a steam-air mixture) and is thereby heated. On the one hand, the heating of the mat with a steam-air mixture with a defined dew point is known, such a steam-air mixture also being referred to as moist air. On the other hand, the application of steam (saturated steam or superheated steam without air content) is known.

The mat is preheated with the help of a steam-air mixture (moist air) as a rule in a double-belt preheating device, in which the pressed material mat is flowed through with a steam-air mixture with a set dew point. The moist air is fed to the mat on the upper or lower side and sucked off on the opposite side, with the major part of the steam contained in the mixture condensing in the mat and heating the mat to the dew point set in the moist air (equal to the preheating temperature) becomes. The preheating temperature is usually not more than 75 ° C in order to prevent the glue from pre-hardening in the press before the panel has reached its final thickness. Overall, such steam-air preheating can increase the production capacity through the heat input in front of the press.

The preheating with steam, which is also known as an alternative, generally leads to heating only of the cover layers of the pressed material mat or to heating of limited portions of the mat on the upper and lower sides. In the course of the application of steam, a temperature of approx. 100 ° C is usually reached on the mat surface, which depending on the amount of steam supplied in a more or less broad transition range to the (initial) temperature of the mat on the forming line and consequently drops before entering the preheater. Such a preheating process by (two-sided) steam injection also leads to an overall increase in production capacity due to the amount of heat introduced into the mat, but this is generally less than with uniform preheating with humid air (steam-air mixture).

A method for preheating grit to a predeterminable preheating temperature in the course of the production of wood-based panels by hot pressing a grit mat in a continuous press or a cycle press is z. B. from the DE 44 23 632 A1 known. Preheating is carried out with an air-conditioned fluid consisting of air and water vapor, which flows through the grit. The fluid has a temperature that is the dew point difference higher than the dew point and the flow rate of the fluid on the one hand, the dew point on the other hand and also the dew point difference are selected so that the specified preheating temperature of the heated spreading material is set. Condensation of the water vapor in the grit is accepted and the humidity of the heated grit is adjusted, if necessary, by additional process measures.

The DE 197 01 596 C2 describes a method and a system for preheating pressed material mats made of glued grit, the pressed material mat being subjected to a flow treatment in a preheating system in which it is exposed to a conditioned fluid made of air and water vapor at a temperature of below 100 ° C with a set dew point and a the set dew point difference is flowed through. During the flow treatment in the direction of the mat thickness, the press material mats are simultaneously traversed by the same air-conditioned fluid and in the same specific volume flows, with condensation fronts forming in the press material mats, which migrate towards one another in the press material from the surface of the press material mat and from the lower surface of the press material mat .

The treatment of a litter mat with a steam-air mixture is also known in connection with the production of biodegradable insulation boards (cf. DE 196 35 410 A1 ). The mat or fleece is first compressed to the desired plate thickness and then a steam-air mixture is introduced into the compressed fleece in a heating zone over a period of 10 to 20 seconds, avoiding pre-hardening of the binding agent. In a further treatment step, a stream of hot air is passed through the compacted fleece for curing and drying. The system known in this respect is therefore not used to preheat a mat for subsequent pressing in a separate press, but in the double belt press both preheating via a steam-air mixture and curing and drying of the mat using hot air takes place.

Methods and devices for preheating pressed material mats in the course of the production of wood-based panels are moreover from the EP 2 213 432 A1 and the EP 2 588 286 B1 known.

Furthermore, from the DE 44 15 276 A1 a method of the type described above is known in which the preheating device is operated with an air-conditioned fluid composed of air and water vapor, which fluid has a temperature of below 100 ° C. and a relative humidity of over 30%. The preheating device can have several fluid chambers which are arranged one behind the other and which can belong to the same fluid circuit. However, the opposite fluid chambers can also each belong in pairs to a separate fluid circuit.

The methods and systems known from practice for preheating a mat of material to be pressed before it enters a press have basically proven themselves. However, there is room for improvement, on the one hand in terms of production capacity and on the other hand in terms of panel properties. - This is where the invention comes in.

Proceeding from the known prior art, the invention is based on the object of creating a method for preheating a pressed material mat with which the production capacity can be increased while at the same time optimizing the board properties. In addition, a corresponding preheating device and a system for the production of wood-based panels are to be created.

To solve this problem, the invention teaches a method for preheating a pressed material mat with the features of claim 1. According to the invention it is provided that the pressed material mat in the double-belt preheating device is initially set in a first stage with a first heating unit with a steam-air mixture Dew point (i.e. with a set dew point temperature) and usually with a (set) A temperature of less than 100 ° C. is applied, which flows through the mat from one side or surface to the opposite side or surface and is thereby heated to a first temperature T1 over the entire mat thickness and
that the pressed material mat in the double-belt preheating device is then acted upon on both sides with (pure) steam or with a steam-air mixture in a second stage with a second heating unit and thus only the surface layers close to the surface are heated to a second temperature T2, which is higher than the first temperature is T1. Steam particularly means water vapor.

A steam-air mixture flows through the mat in the first stage and steam is applied on both sides in the second stage.

Alternatively, however, preheating with a (first) steam-air mixture with a set dew point and a (set) temperature of less than 100 ° C can take place in the first stage, and in the second stage a (second) Steam-air mixture, which, however, has a higher dew point and / or a higher temperature than the first steam-air mixture of the first stage, so that the surface layers near the surface are heated in this second stage.

The invention is based on the knowledge that preheating with a steam-air mixture (humid air) on the one hand and preheating with steam (saturated steam or superheated steam) act differently and lead to different effects in the production process, so that the production process is combined , two-stage approach can be optimized overall. Because with the help of preheating by means of a steam-air mixture, a significantly higher amount of heat can be introduced into the entire mat when it is heated to the dew point than with conventional steam preheating, which leads exclusively or essentially to heating of the top layers. This allows the production capacity to be increased more by preheating using a steam-air mixture than with a steam preheating process. However, preheating the entire mat using moist air leads to a more or less pronounced "flattening" of the density profile, since a preheated mat can be compacted with less pressure because both mat moisture and mat temperature are raised during preheating. As a result, the minimum density or the middle layer density increases in a completely preheated mat, which basically has a positive effect on the transverse tension. The disadvantage, however, is that the top layer density decreases more or less strongly, with correspondingly negative effects on z. B. the bending stiffness.

In contrast to preheating with the help of a steam-air mixture, preheating with steam causes the top layers to become warmer and more humid and thus also softer, which means that very distinctive top layers of high density can be created while the cold and "hard" middle of the mat leads to rather low mat densities in the middle of the panel. In this way, the production capacity can only be increased slightly because of the low heat input in the middle of the mat. However, if higher amounts of steam are injected into the top layers of the mat in order to increase production capacity, there is a risk that an ever larger proportion of the weight per unit area of the mat will be “consumed” in the top layers and that there will no longer be enough material available in the middle of the board to cover the to achieve the mat density required for the transverse tension.

According to the invention, the two-stage preheating by means of a steam-air mixture in a first stage and by means of steam (or alternatively also a steam-air mixture with a higher dew point) in the second stage increases both the production capacity and high material savings and an optimal Density profile (related to the important panel properties such as transverse tensile strength and flexural strength) is achieved simultaneously in a common preheating process and in a single preheating device. The previously “opposing goals”, namely high production capacity, high material savings and an optimal density profile, are achieved together in a combined process.

In the two-stage preheating process according to the invention, the preheating takes place in the first stage with a steam-air mixture and consequently with moist air with a set dew point and set temperature which is the so-called dew point difference above the dew point. The dew point (which is also referred to as the dew point temperature) denotes the temperature at which the air in the steam-air mixture is just saturated with the amount of steam present (in particular water vapor). Below the dew point, condensation of the water vapor occurs as a result of oversaturation, so that the water vapor condenses like a dew. At the dew point, the relative humidity is 100% and the air is (just) saturated with water vapor. The dew point or the dew point temperature (and, if applicable, the temperature or dew point difference) of the steam-air mixture can be set in a targeted manner using known means and measures. For this purpose z. B. air (z. B. with the help of a heat exchanger) heated to a desired temperature and then be mixed with a mixing device with (fresh) steam (e.g. water vapor) in the desired ratio. A steam-air mixture with a dew point of 50 ° C to 85 ° C, preferably 60 ° C to 75 ° C, for example, is preferred for preheating in the first stage. B. about 70 ° C used. In the course of the preheating in the first stage, in which the steam-air mixture completely flows through the mat over the entire thickness, the steam condenses in the mat and the mat is preferably heated to the set dew point, i.e. the preheating temperature T1 of the mat in the first stage preferably corresponds to the dew point temperature of the steam-air mixture used, so that the pressed material mat is preferably heated to a temperature T1 of 50 ° C to 85 ° C, preferably 60 ° C to 75 ° C, in the first stage.

The steam-air mixture flows through the press mat in the first stage from one surface to the opposite surface, preferably by feeding it on one surface (e.g. the top) and on the opposite side (e.g. the bottom) is sucked off. In principle, it may be sufficient in the first stage to provide a flow through the mat in one direction only in a single zone, e.g. B. from top to bottom or alternatively from bottom to top. In a preferred development, however, the first stage for steam-air preheating consists of at least two zones arranged one behind the other, in which the steam-air mixture with the set dew point flows through the mat in alternating, opposite directions. So z. B. in the first stage, the steam-air mixture pressed into the mat from above and sucked out of the mat from below and pressed into the mat from below in the second zone and sucked out of the mat from above, preferably the same Mixture is used with the same parameters, in particular identical dew point.

In this way, a particularly homogeneous heat input and thus even preheating of the mat over the entire thickness can be achieved.

In contrast, in the second stage there is strong heating only of the outer layers close to the surface, preferably to a temperature T2 of more than 85 ° C., preferably more than 95 ° C., e.g. B. about 100 ° C or more. For this purpose, (pure) steam (for example water vapor) is particularly preferably pressed into the mat from both opposite sides or surfaces at the same time, without suction taking place on the respective opposite side. The mat, which is preheated to temperature T1 over the entire thickness in the first stage for the purpose of increasing capacity, is consequently further heated to temperature T2 in the second step in the area of the cover layers, preferably by means of steam, so that with the help of the mats with warmer and softer cover layers, a particularly high cover layer density with the described advantages of the board properties can be achieved. While the mat is consequently completely traversed by a steam-air mixture in the first stage, in the second stage the mat is preferably acted upon by steam from both sides at the same time without opposite suction.

In an alternative embodiment, however, a steam-air mixture instead of steam can also be used in the second stage, which is used for heating the outer layer. In this case, however, a steam-air mixture and consequently moist air with a higher dew point and optionally higher temperature is used in the second stage, i.e. H. the steam-air mixture in the second stage has a higher dew point and / or a higher temperature or dew point difference than the steam-air mixture in the first stage, which is responsible for the uniform warming of the mat. In the second stage, the steam-air mixture can be pressed into the mat from both sides at the same time, just like with a pure steam application. Alternatively, however, there is also the possibility that the steam-air mixture in the second stage (as in the first stage) flows through the mat in one direction and is consequently pressed into the mat from one side and sucked off on the other side. In the second stage, however, it is advisable to press the steam-air mixture (with a higher dew point) into the mat in two consecutive zones in alternating, opposite directions and / or to suck it through the mat.

Overall, a particularly advantageous preheating takes place in the two-stage process according to the invention, which leads to both an increase in production capacity and an optimization of the panel properties, so that panels with good properties (in particular with regard to transverse tensile strength and flexural strength) have increased production capacity and consequently in a particularly economical manner can be produced.

There is also the option of not only preheating the mat in the double-belt preheating device, but also compressing it, namely after the second preheating stage. For this purpose, a compacting device can be arranged in the double-belt preheating device behind the second heating device.

The invention also relates to a double-belt preheating device for heating a pressed material mat, in particular with or after a Method of the type described. This double-belt preheating device has an upper, endlessly circulating, gas-permeable conveyor belt and a lower, endlessly circulating, gas-permeable conveyor belt, between which a treatment gap is formed through which the mat can be guided along the transport direction (by means of the driven conveyor belts) is. Furthermore, the double-belt preheating device has a heating unit, namely a first heating unit, which is designed as a steam-air supply device and with which the pressed material mat (in a first treatment stage) with a steam-air mixture with an adjustable dew point (and adjustable temperature ) can be acted upon, this steam-air mixture (moist air) flowing through the mat from one surface to the opposite surface and thereby heating the mat over the entire thickness of the mat, preferably to the set dew point of the steam-air mixture. According to the invention, the double-belt preheating device additionally has a second heating unit which is arranged downstream of the first heating unit and consequently the steam-air supply device in the transport direction and which is used to treat the pressed material mat in a second treatment stage. The second heating device is preferably designed as a steam supply device with which (pure) steam (preferably water vapor) can be applied to the mat for heating only the surface layers close to the surface. Alternatively, however, the second heating device can be designed as a steam-air supply device with which the mat for heating only the surface layers can be exposed to a (second) steam-air mixture which has a higher dew point and / or a higher temperature than that (first) steam-air mixture of the first heating unit.

The first heating unit, which is designed as a steam-air supply device, preferably has at least one supply-suction pair with a supply, e.g. B. a feed box, on one side of the mat and a suction, z. B. a suction box on the opposite side of the mat. The supply and / or the discharge can corresponding boxes, registers and / or plates, e.g. B. perforated plates, grid plates or the like. There is also the possibility that several such devices are arranged distributed over the width of the mat, so that the application and / or suction profile is variable over the width of the mat.

Particularly preferably, however, the first heating unit not only has a single supply-suction pair for a flow through the mat in one direction, but several supply-suction pairs arranged one behind the other are provided, which are preferably designed for opposite flow directions, so that the mat is traversed one after the other in at least two consecutively arranged zones in opposite directions. So z. B. on the top first a first feed, z. B. a first feed box and on the opposite bottom a first suction, z. B. a first suction box can be arranged. Behind it, a second feed, z. B. a second feed box and on the top a second suction, z. B. a second suction box can be provided. The reverse arrangement is also possible.

The second heating unit is preferably designed as a (pure) steam supply device and has at least one supply pair with one supply on each side of the mat, e.g. B. on a feed box. This can be used from both sides via the feeders, for B. feed boxes, simultaneously press steam (or alternatively a steam-air mixture) into the mat from both sides in order to heat the top layers.

In an alternative embodiment, the second heating unit (e.g. as a steam-air supply unit) can have several supply-suction pairs arranged one behind the other, which are designed for opposite flow directions, so that the construction of the second heating unit essentially corresponds to the construction of the first heating unit may correspond, but the second heating unit is designed for the application of a steam-air mixture with a higher dew point.

The conveyor belts of the preheating device are preferably designed as sieve belts.

The double-belt preheating device can optionally be equipped with a compacting device for compacting the mat, this compacting device preferably being arranged downstream of the second heating unit. There is consequently first of all preheating with the aid of the first heating unit and the second heating unit and then optionally compression with the compacting device. Such Kompatkieinrichtung can z. B. have an upper and a lower compacting roller, the upper and / or the lower compacting roller with at least one power means, for. B. a press cylinder, can be acted upon or can be acted upon. In the press cylinders it can be, for. B. act to hydraulic cylinders. Optionally, subsequent to the preheating, there is a subsequent compression to vent the mat of material to be pressed, with the aim of displacing air on the mat, so that the subsequent pressing process in the downstream press is optimized and the risk of blowing out is reduced becomes. In this way, an increased feed rate of the system and thus an even higher profitability is achieved.

According to the invention, the double-belt preheating device described and its operation for preheating the pressed material mat are in the foreground. However, the invention also relates to a plant for the production of wood-based panels, with at least one scattering device for producing a pressed material mat and with a double-belt preheating device of the type described and with a press for pressing the preheated pressed material mat. This press, which is preferably designed as a continuously operating double belt press, is consequently preferably arranged behind the double belt preheating device according to the invention. The double-belt preheating device is therefore not used to manufacture a finished product, but only to preheat a pressed material mat within the manufacturing process, i.e. H. the preheated mat of material to be pressed is then pressed into the finished product in a separate press using pressure and heat.

The press downstream of the preheating device is preferably designed as a double belt press. She has z. B. an upper heating plate and a lower heating plate and in the upper part of the press and in the lower part of the press endlessly circulating press belts, for. B. steel press belts. These press belts are z. B. with the interposition of rolling element assemblies (z. B. roller bars) supported on the heating plates or press plates. One of the heating plates or both heating plates are acted upon by press cylinders, which are supported on the press frame (e.g. on the press frame). The preheating device according to the invention can then consequently be integrated into a conventional manufacturing process and combined with known double belt presses.

The preheating device is particularly preferred in the manufacture of fiberboard, e.g. B. MDF board (Medium Densified Fiber) used, d. H. A pressed material mat made of wood fibers is preheated. Alternatively, it can also be used for chipboard and OSB panels and consequently the preheating of chipboard and OSB mats.

• 1 einen Ausschnitt aus einer Anlage zur Herstellung von Holzwerkstoffplatten in einer vereinfachten Darstellung,
• 2 eine schematisch vereinfachte Seitenansicht einer Doppelband-Vorwärmeinrichtung aus der Anlage nach 1,
• 3a, 3b Temperatur- und Dichteprofil einer Matte bzw. Platte ohne Mattenvorwärmung
• 4a, 4b Temperatur- und Dichteprofil einer Matte mit einer Mattenvorwärmung mittels eines Dampf-Luft-Gemisches,
• 5a, 5b Temperatur- und Dichteprofil einer Matte mit einer Vorwärmung mittels Dampf und
• 6a, 6b Temperatur- und Dichteprofil mit einer erfindungsgemäßen zweistufigen Vorwärmung mit sowohl Dampf-Luft-Gemisch als auch Dampf.

In the following, the invention is explained in more detail with reference to drawings, which only represent an embodiment. Show it

• 1 a section from a plant for the production of wood-based panels in a simplified representation,
• 2 a schematically simplified side view of a double belt preheating device from the system according to 1 ,
• 3a , 3b Temperature and density profile of a mat or plate without mat preheating
• 4a , 4b Temperature and density profile of a mat with mat preheating by means of a steam-air mixture,
• 5a , 5b Temperature and density profile of a mat with preheating by means of steam and
• 6a , 6b Temperature and density profile with a two-stage preheating according to the invention with both a steam-air mixture and steam.

In 1 a simplified system for the production of wood-based panels is shown in a continuous flow. First, with the help of a scattering device that is only indicated 1 the grit to be compressed (e.g. wood fibers) to form a grit mat or pressed material mat 2 sprinkled on a belt conveyor. The grit mat produced in this way is placed in a double-belt preheater 3 pretreated and then in a continuously operating press 4th using pressure and heat to form a plate or a plate-shaped strand, e.g. B. a fiber board (preferably MDF board) pressed. The press 4th is preferably designed as a double belt press, which has an upper heating plate and a lower heating plate and endlessly circulating press belts (e.g. steel press belts) in the press upper part and in the press lower part, these press belts with the interposition of rolling element assemblies (e.g. roller bars) on the press plates ( Heating plates) are supported. One of the heating plates or both heating plates are acted upon by press cylinders, which are supported on the press frame (e.g. on the press frame).

About the pressing process within the press 4th To optimize, according to the invention, the mat of material to be pressed is preheated 1 with the help of the in 1 only indicated preheating device 3 which, by the way, are in 2 is shown in more detail. This has an upper, endless, gas-permeable conveyor belt 5a , e.g. B. a sieve belt 5a , and a lower, endlessly circulating, gas-permeable conveyor belt 5b , e.g. B. a sieve belt 5b on. The conveyor belts or sieve belts 5a , 5b are each around several rollers or cylinders 6th out of which at least one roller is designed as a drive roller for the upper part and the lower part. Between the conveyor belts 5a , 5b a treatment gap is formed through which the mat 2 is passed along the transport direction X from an inlet E to an outlet A. The area of the conveyor belt 5a , 5b which extends from inlet E to outlet A and in which consequently the pressed material mat 2 is performed is referred to as the forerun V and the subsequent area of the Belts starting at outlet A to inlet E form the return R, which in turn merges into the forward V at inlet E.

The double belt preheater 3 has a first heating unit immediately behind the inlet E. 7th which is designed as a steam-air supply device and with which the pressed material mat can be acted upon with a steam-air mixture with an adjustable dew point, which flows through the mat from one surface to the opposite surface and thereby heats it over the entire mat thickness. In the illustrated embodiment, the first heating unit 7th several supply-suction pairs arranged one behind the other 8th on each one feeder 8a and a suction device on the opposite side of the mat 8b have, this as a feed box 8a and suction box 8b can be formed. Details are not shown. The first feed-suction pair 8th has an upper feed 8a and a lower suction 8b on, while the second feed-suction pair 8th a lower feeder 8a and an upper suction 8b having. In the first treatment stage within the steam supply device 7th are consequently two zones arranged one behind the other 8th realized in which in opposite directions a steam-air mixture through the mat 2 is pushed through and sucked through the mat. The pressed material mat 2 is consequently in one of the first heating unit 7th formed first stage is acted upon with a steam-air mixture with set dew point (and set temperature), which flows through the mat from one surface to the opposite surface and thereby heats over the entire mat thickness to a first temperature T1, which (approximately) the ( corresponds to the preset) dew point temperature of the steam-air mixture.

Furthermore, the preheating device 3 a second heating unit 9 on that in the transport direction X behind the first heating unit 7th is arranged. In the exemplary embodiment, this is designed as a steam supply device with which the mat 2 for heating only the surface layers close to the surface can be acted upon with (pure) steam. To this end, the steam supply device 9 a pair of feeders with one feeder on each side of the mat 9a for the steam on, these feedings 9a z. B. can be designed as feed boxes. With the feeders 9a steam (e.g. steam) is pressed into the mat from both sides at the same time, the steam e.g. B. may have a temperature of 100 ° C or more. With this second heating unit 9 steam enters the mat on both sides 2 pressed and thereby only the near-surface cover layers are heated to a second temperature T2, which is higher than the first temperature T1, to which the mat in the first heating unit 7th is heated.

With the in 2 The preheating device shown is followed by a two-stage preheating of the press mat, in the first stage with the help of a steam-air mixture with which the press mat 2 is heated to a first temperature T1 uniformly over the entire mat thickness. In the second stage, only the surface layers near the surface are heated further to the second temperature T2. The heating in the first stage results in a high input of heat, which leads to increased production capacity. The increase in temperature in the outer layers close to the surface leads to panels with improved properties in the course of the subsequent pressing process, in particular with regard to flexural strength and transverse tensile strength.

In detail, the advantages achieved according to the invention are illustrated using the graphic representations in FIG 3a , 3b to 6a , 6b explained in more detail. The 3a , 4a , 5a and 6a each show a temperature profile over the thickness of the plate, ie the temperature of the mat entering the press and the temperature of the plate after the press are plotted as a function of the location within the plate in percent based on the plate thickness. With a plate thickness of z. B. 16 mm means 0% 0 mm and 100% 16 mm, ie the value 0% relates to one plate surface and the value 100% relates to the opposite plate surface and the values in between relate to the inside of the plate. It should be noted that the thickness of the mat is of course significantly reduced in the pressing process in the continuous press, e.g. B. on the plate thickness of 16 mm.

The 3b , 4b , 5b and 6b each show density profiles, on the one hand for the press material mat before it enters the press (e.g. DPo in 3b) and on the other hand for the finished pressed plate behind the press, ie the density of the plate is plotted as a function of the plate thickness or of the location within the plate based on the plate thickness.

The 3a and 3b firstly show the conditions in the production of a fiberboard (e.g. MDF board) without any preheating before the press. The temperature To of the press mat after the spreading station is z. B. about 30 ° C, so that the mat enters the press without preheating with a temperature To = 30 ° C with a temperature profile TPo and the temperature profile after the press TP _P the plate with a minimum temperature of e.g. B. 110 ° C at the outlet of the press. The mat density ρ _M is according to 3b e.g. . B. 120 kg / m ³ , homogeneously over the entire thickness of the pressed material mat (density profile DPo). In the course of pressing, this turns out to be in 3b density profile also shown DP _p a, the plate having an average density ρ _P of z. B. 550 kg / m ³ . In 3b it can be seen that the panel has a relatively low density in the center of the panel and a relatively high density in the outer cover layers.

The 4a , 4b show the influence of the heating of the entire press mat with a basically known preheating by means of a steam-air mixture (here abbreviated in the indices with DL), which z. B. has a dew point of 70 ° C, so that the mat is preheated over the entire width to a temperature T ₁ of (about) 70 ° C. In 4a the homogeneous temperature profile TPo with the mat temperature To after the scattering station and consequently before the preheating device is shown at 30 ° C. Furthermore, the mat temperature T _{1 is shown} behind the preheating device, ie there is essentially uniform preheating to about 70 ° C. (temperature profile TP _DL ). The press program is adapted to this preheating so that the same temperature profile at the press outlet TP _P as in 3a is achieved, but with increased production capacity due to the upstream preheating. In 4b is again the density profile for comparison DP _P of the finished plate without preheating (as in 3b) shown. Furthermore is the density profile DP _DL shown, which occurs due to the preheating described with the steam-air mixture. It can be seen that the density is increased in the middle of the mat, which has a positive effect on the transverse tension. On the other hand, however, the surface layer densities decrease compared to processing without preheating, which is undesirable.

The 5a , 5b show the influence of preheating of the outer layers through conventional steam application on both sides. It can be seen that the double-sided application of steam at a temperature of z. B. 100 ° C there is a strong increase in the mat temperature in the area of the surfaces or the top layers (cf. 5a) . The temperature profile is based on the homogeneous temperature profile TPo TP _D the mat by preheating it with steam. This leads to a plate with high density in the top layers (cf. 5b) . The density profile is shown DP _P without preheating and the density profile DP _D the plate by steam preheating. The disadvantage here are the relatively low densities in the middle of the plate, which overall lead to the production capacity in the preheating process according to FIG 5a , 5b is not increased as much as in the procedure after 4a , 4b .

The 6a , 6b show the influence of the two-stage preheating according to the invention using initially a steam-air mixture in a first stage and then using steam in a second stage. In the first stage, the mat temperature is raised over the entire thickness of the mat to the temperature T ₁ and the homogeneous temperature profile TP _S1 achieved. In the subsequent second stage, the temperature is raised to the temperature T ₂ of about 100 ° C. only in the area of the outer layers and the temperature profile is increased by the application of steam TP _S2 reached. The density profile resulting from the subsequent pressing process DP _K combined preheating is in turn in 6b compared to a density profile DP _P shown without preheating. Out 6b It consequently results that the method according to the invention with an increase in capacity results in a density profile that is fundamentally advantageous DP _K results in a similar way to without preheating or even an even further optimized density profile with regard to transverse tensile strength and flexural strength, as on the one hand the density in the middle of the board is increased and on the other hand the density in the area of the outer layers is increased. It is important that this equivalent or even improved sealing profile is achieved with high production capacity at the same time, since according to 6a A high and even heat input into the mat is achieved through preheating, so that the subsequent pressing process can be carried out particularly economically with high capacity.

A system or its preheating device shown by way of example in the figures also has the usual means for generating, setting, supplying and controlling or regulating the steam and the steam-air mixture, e.g. B. Heat exchangers, mixing devices, etc. This allows the parameters of the steam and in particular the steam-air mixture mentioned, in particular the dew point and the temperature or dew point difference to be set.

Claims (16)

Method for preheating a pressed material mat (2) before it enters a press (4), in particular during the production of wood-based panels, the pressed material mat (2) having a double-belt preheating device (3) with an upper, endless, gas-permeable conveyor belt (5a) and a lower, endlessly circulating gas-permeable conveyor belt (5b) runs through, the pressed material mat (2) being acted upon by a heated fluid containing steam and thereby heated, the pressed material mat (2) initially in the double-belt preheating device (3) in a first stage with a first heating unit (7) with a A set dew point is applied to the steam-air mixture, which flows through the press mat (2) from one surface to the opposite surface and is thereby heated to a temperature (T ₁ ) over the entire mat thickness and the press mat (2) in the double belt preheating device (3) then in a second stage with a second heating unit (9) steam or a steam-air mixture is applied to both sides and only the surface layers near the surface are heated to a second temperature (T ₂ ), which is higher than the first Temperature (T ₁ ). Procedure according to Claim 1 , characterized in that in the second stage steam or a steam-air mixture is pressed simultaneously into the two opposite surfaces of the pressed material mat (2). Procedure according to Claim 1 or 2 , characterized in that in the second stage a steam-air mixture or steam is pressed into the pressed material mat (2) and / or sucked through the pressed material mat (2) in at least two consecutive zones in alternating, opposite directions. Method according to one of the Claims 1 to 3 , characterized in that in the first stage in at least two zones arranged one behind the other, a steam-air mixture is pressed into the pressed material mat (2) in alternating, opposite directions and / or sucked through the pressed material mat (2). Method according to one of the Claims 1 to 4th , characterized in that the pressed material mat (2) is heated in the first stage to a temperature (T ₁ ) which corresponds to the dew point of the steam-air mixture. Method according to one of the Claims 1 to 5 , characterized in that the pressed material mat (2) is heated in the first stage with the steam-air mixture over the entire thickness to a temperature (T ₁ ) of 50 ° C to 85 ° C, preferably 60 ° C to 75 ° C becomes. Method according to one of the Claims 1 to 6th , characterized in that in the second stage the two surface layers of the pressed material mat (2) with the steam or the steam-air mixture to a temperature (T ₂ ) of more than 85 ° C, preferably more than 95 ° C, z . B. about 100 ° C, are heated. Method according to one of the Claims 1 to 7th , characterized in that the pressed material mat (2) is compacted in the double belt preheating device (3) after the second stage with a compacting device (10) downstream of the second heating unit (9). Double belt preheating device (3) for heating a pressed material mat (2), in particular using a method according to one of the Claims 1 to 8th , with an upper, endlessly circulating gas-permeable conveyor belt (5a) or in a lower, endlessly circulating gas-permeable conveyor belt (5b), between which a treatment gap is formed through which the pressed material mat (2) can be passed along the transport direction (X), with a first heating unit (7), which is designed as a steam-air supply device, and with which the pressed material mat (2) can be acted upon with a steam-air mixture with an adjustable dew point, which flows through the pressed material mat (2) from one surface to the opposite surface and thereby heated over the entire thickness of the mat, characterized in that the first heating unit (7), ie the steam-air supply device, is followed in the transport direction (X) by a second heating unit (9), the second heating device (9) either is designed as a steam supply device, with which the mat for heating only the near-surface deck layers can be acted upon with steam or is designed as a steam-air supply device with which the pressed material mat (2) can be acted upon for heating only the surface layers close to the surface with a steam-air mixture, which has a higher dew point or a higher temperature than the steam Having air mixture of the first heating unit (7). Device according to Claim 9 , characterized in that the first heating unit (7), ie the steam-air supply device, at least one supply-suction pair (8) with a supply (8a), for. B. with a feed box, on one side of the mat and a suction (Sb), z. B. a suction box, on the opposite side of the mat. Device according to Claim 9 or 10 , characterized in that the first heating unit (7) has several supply-suction pairs (8) arranged one behind the other, which are preferably designed for opposite directions of flow, so that a steam-air mixture is pressed and successively in opposite directions through the pressed material mat 2 / or is sucked. Device according to one of the Claims 9 to 11 , characterized in that the second heating unit (9), the z. B. is designed as a steam supply device, with a supply pair on both sides of the mat each have a feed (9a), e.g. B. a feed box, with which the pressed material mat (2) can be acted upon simultaneously from both sides with steam or a steam-air mixture. Device according to one of the Claims 9 to 12 , characterized in that the second heating unit (7), e.g. B. as a steam-air supply unit, several successively arranged supply-suction pairs, which are designed for opposite flow directions, so that a steam-air mixture is pressed one behind the other in opposite directions through the mat and / or sucked through the mat . Device according to one of the Claims 9 to 13 , characterized in that the conveyor belts (5a, 5b) are designed as sieve belts. Device according to one of the Claims 9 to 14th , characterized in that the second heating unit (7) is followed by a compacting device (10) for compacting the pressed material mat, which preferably has an upper and a lower compacting roller (11), the upper and / or lower compacting roller (11) with at least one power means (12), e.g. B. a press cylinder, can be acted upon or can be acted upon. Plant for the production of wood-based panels, with at least one scattering device (1) for producing a pressed material mat (2), a double-belt preheating device (3) according to one of the Claims 9 to 15th for preheating the pressed material mat and a press (4) for pressing the preheated pressed material mat (2) using pressure and heat.

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