EP1079961A1

EP1079961A1 - Method and device for producing shaped bodies

Info

Publication number: EP1079961A1
Application number: EP99920826A
Authority: EP
Inventors: Hans-Joachim Iredi; Ove-Walter Cornils; Hubertus Japes; Klaus Linde; Franz-Josef Wilbois
Original assignee: Valmet Panelboard GmbH
Current assignee: Metso Panelboard GmbH
Priority date: 1998-05-19
Filing date: 1999-04-30
Publication date: 2001-03-07
Anticipated expiration: 2019-04-30
Also published as: CN1306471A; ATE226496T1; NZ508090A; DE59903178D1; US6562162B1; CA2332144C; WO1999059788A1; AU743285B2; ES2186358T3; AR019302A1; EP1079961B1; AU3825799A; CN1113731C; CA2332144A1

Abstract

The invention relates to a method for producing shaped bodies, especially fibre boards, particle boards or similar. According to said method, fibres or cellulose- or lignocellulose-containing particles with added binders are dispersed to form a nonwoven material and then preheated. This nonwoven material is then pressed to form the shaped body, heat and pressure being applied. The nonwoven material consisting of pre-pressed fibres or similar particles is pre-heated by conveying heat energy from inside the nonwoven outside, to the surface. The invention also relates to a device for carrying out the inventive method.

Description

Method and device for producing molded articles

A process for the production of moldings, in particular of fibreboard, particle board or the like, is described in which binder-added fibers, cellulose- or lignocellulose-containing particles are scattered and preheated to a nonwoven before the nonwoven is supplied with heat and Pressure is pressed to the shaped body. Furthermore, the invention is directed to a device for producing shaped bodies, in particular fiberboard, particle board or the like, the device comprising a scattering station, a molding line, a pressing station and a heating device upstream of the pressing station for heating a from the scattering station to the molding line scattered fleece before entering the pressing station.

Such a device and a corresponding method are known from DE-PS 39 14 106. In the device described in this document, the heating device is arranged in the area of the inlet drums of the press station in order to increase the output of molded articles or to reduce the length of the press for a given output.

A disadvantage of such a device is that a relatively large amount of thermal energy has to be supplied to the nonwoven both in the heating device and in the pressing station and that the transport speed of the nonwoven does not exceed a certain maximum speed. may proceed, since otherwise a complete heating of the fleece over its entire cross-section is not possible.

It is an object of the invention to design a method and a device of the type mentioned at the outset in such a way that the heat energy to be supplied can be reduced, while at the same time uniform heating of the fleece is maintained. A further object is to further develop a method and a device of the type mentioned at the outset in such a way that they can be used even more flexibly and, in particular, the output of moldings can be increased or the length of the device can be reduced for a given output.

The part of the task relating to the method is achieved on the basis of a method of the type mentioned at the outset in that the preheating of the fleece consisting of the pre-compressed or pre-pressed fibers or similar particles by supplying thermal energy from the inside of the fleece to the outside of the surface of the Fleece out. Accordingly, the part of the object relating to the device is achieved in a device of the type mentioned at the outset in that the heating device is designed to supply heat from the inside of the fleece to the outside towards the surface of the fleece.

Thus, while in the subject of DE 39 14 106 the thermal energy of both the heating device and the pressing station takes place from the outside of the nonwoven toward the inside of the nonwoven, the direction of supply of the thermal energy in the heating device is reversed according to the invention. Since the heat supplied to the fleece in the press station via the press rolls takes place from the outside to the inside of the fleece, it is cheaper to heat the inside of the fleece in the preheating phase, whereas heating the outside is not so essential. The combination of preheating from the inside to the outside and heat treatment from the outside to the inside of the press station ensures that the nonwoven is completely and uniformly heated over its entire cross-section.

Furthermore, the energy loss of the supplied thermal energy, which takes place on the way between the heating device and the pressing station, is significantly less if the fleece has a "hot core" than if the fleece in the heating device is heated via its outer sides.

Energy savings can thus be achieved on the one hand by not having to heat the fleece in the heating device completely to the outside and on the other hand by reducing the energy losses between the heating device and the pressing station.

According to an advantageous embodiment of the invention, at least one additive, in particular a catalyst for the binder contained in the nonwoven, is likewise introduced into the nonwoven from the inside of the nonwoven to the surface of the nonwoven.

By adding one or more additives, also from the inside of the fleece to the surface of the fleece, it is possible, for example, to accelerate the setting process taking place in the fleece. By adding the additives from the inside Ren of the fleece forth the thickness of the fleece to be penetrated is reduced, so that a more uniform penetration of the fleece with the additives takes place. According to the invention, the critical area of the fleece, in particular, is optimally penetrated with the additives.

The above-mentioned object is further achieved by first scattering two separate nonwovens to form the nonwoven, each of which is brought together in such a way that the sides of the separate nonwovens facing one another the inside and the sides of the separate nonwovens facing away from one another, the top and the Form the underside of the fleece.

According to the invention, two nonwovens, initially scattered separately, are produced, which are brought together to form a uniform overall nonwoven. The sides of the separate nonwovens lying on top of one another after the merging thus form the inner region and the sides facing away from one another form the upper and lower sides of the entire nonwoven. The two separate nonwovens can thus be heated from their mutually facing sides, which later form the inner region of the entire nonwoven, by supplying thermal energy to the separate nonwovens from these sides, facing away from one another.

The separate nonwovens can be brought together by machine or manually. For example, one of the separate nonwovens can be transported in a conventional manner on a transport device, for example a conveyor belt, while the second nonwoven is manually placed from above onto the lower nonwoven lying on the transport device. Instead of separate scattering of two nonwovens, a nonwoven with a mat-shaped structure can be used according to the invention, which is cut open essentially parallel to its top and bottom, the heat supply through the sliding surfaces both towards the top and the bottom of the Fleece is done. For this purpose, a separating device, in particular in the form of a cutting device, is preferably provided, with which the nonwoven can be divided into at least two, in particular a lower and an upper, partial nonwoven, the heating device being arranged in the region between the partial nonwovens.

The partial nonwovens preferably have essentially the same thickness, so that uniform heating of the nonwoven from the inside to the outside is achieved both to the top and to the bottom of the web. The heating device advantageously lies directly on the cut surfaces of the partial nonwovens, since energy loss is largely avoided in this way.

The separating device is preferably designed as a saw, in particular as a band saw, preferably as an endless band saw, the cutting direction of the cutting device advantageously being directed essentially parallel to the surface of the molding line against the transport direction of the fleece. In this way, a simple supply of thermal energy from the inside of the fleece to the outside is possible. Furthermore, the fleece can be separated into two partial fleeces directly during the transport of the fleece on the molding line in the direction of the pressing station, without the transport process being interrupted or otherwise impaired. The invention can thus be used both in continuous Manufacture as well as used in the discrete manufacture of moldings.

The fleece is preferably pre-pressed before preheating, since this avoids tearing or disintegration of the fiber components of the fleece during the cutting process. Furthermore, the invention is preferably used for nonwovens which are made from fibers and not, for example, from chips, since fibers become matted during the pre-pressing and thus give the nonwoven a strength which is advantageous for the subsequent cutting process.

According to a further advantageous embodiment of the invention, the heating device comprises a heating chamber which extends essentially over the entire width of the fleece and which, in their regions facing the partial fleeces, each have in particular slit-shaped outlet openings for discharging heating medium, in particular steam, from the heating chamber in the fleece.

The heating chamber allows the fleece to be heated very easily and evenly across its entire width. Furthermore, the outlet openings can be at least partially closable, in particular by means of a slide element, so that both a control of the amount of the emerging heating medium and of the location at which heating medium is to escape within the fleece can be set.

It is advantageous to provide the heating device as close as possible to the press inlet, so that both the supply of heat and, if appropriate, the The additives are introduced into the fleece immediately before it enters the press nip.

It is also possible to cut the nonwoven asymmetrically, that is to say cut it into partial nonwovens of different thicknesses or to combine partial nonwovens scattered with different thicknesses to form a uniform nonwoven. Furthermore, it is possible to produce not only two, but several partial nonwovens, which may have different or the same thickness.

In order to reduce the friction between the partial nonwovens and the heating device, a vibration device can also be provided according to the invention or the heating device can be set in vibration. The heating device can advantageously be coated with thermal insulation material, for example with Teflon or the like, in particular at its contact points with the partial nonwovens. As a result, premature curing or a tendency to harden the binder contained in the nonwoven material can be avoided. Instead of or in addition to insulation material, the heating device can for example also contain sections, in particular chambers with cooling medium, for example cooled air.

A heating device designed according to the invention can also be designed to supply thermal energy and / or additives in the opposite direction, ie from the outside of the fleece to the inside thereof. Instead of supplying the heating medium and / or the additives via the openings of the heating device, for example on the side, a negative pressure can be applied to these openings, for example Connection of a vacuum device can be generated. Due to the negative pressure generated in this way within the heating device, a heat medium and / or corresponding additives can then be fed to the top and / or bottom of the fleece, whereupon they pass through the respective partial fleece from the outside to the inside of the fleece due to the vacuum be spent there.

Further advantageous embodiments of the invention are specified in the subclaims.

The invention is described below using an exemplary embodiment with reference to the drawings; in these show:

1 shows a longitudinal section through a heating device designed according to the invention with an upstream band saw,

FIG. 2 shows a top view of the device according to FIG. 1,

3 is a partial view of the plan view of FIG. 2 on a larger scale,

4 is a sectional view taken along lines A-A of FIG. 3,

5 is a side view of the device of FIG. 3,

Fig. 6 is a sectional view taken along lines BB of Fig. 5 and Fig. 7 shows a longitudinal section through a further embodiment of the

Invention.

1 shows a fleece 1 which is scattered on a forming line 2 designed as an endless rotating conveyor belt and is transported in the direction of an arrow 3 to a press station 5 formed by two press rolls 4 shown in detail.

The fleece 1 is subjected to pressure and heat via the press rolls 4, so that the desired shaped bodies emerge in the form of plates at the exit of the press station 5.

Arranged in the transport direction in front of the pressing station 5 is a partially shown band saw 6, which is indicated by a partially shown deflection roller 8 which can be rotated about an axis 7 and an endless saw blade 9 guided around the outside of the deflection roller 8.

The band saw 6 is adjustable in height with its saw blade 9, as is indicated by a double arrow 10. In Fig. 1, the position of the band saw 6 is set so that the saw blade 9 is approximately in the middle of the

The height of the fleece 1 comes to lie, the teeth 21 of the saw blade 9 being directed against the transport direction of the fleece represented by the arrow 3, as can be seen from FIG. 2. The saw blade 9 extends substantially horizontally and in a straight line over the entire width of the fleece 1 (see also FIG. 2), so that the fleece 1 at one

Movement along the arrow 3 through the saw blade 9 into an upper and a lower partial fleece 11, 12, each having the substantially same thickness, is cut open. In the area between the band saw 6 and the pressing station 5, a heating device 13 is provided, which is arranged between the upper and the lower partial fleece 11, 12.

The heating device 13 comprises a hollow rail 14 with a heating chamber 15, which extends over the entire width of the fleece 1, as well as an expansion device 16, which adjoins the hollow rail 14 against the transport direction 3, and a merging device 17, which connects the heating chamber 15 in the transport direction 3 .

The widening device 16 has a run-up slope 18 sloping towards the transport direction 3 and its height can be adjusted together with the band saw 6, as is indicated by the double arrow 10. The interior of the expansion device 16 is designed as a cavity 49, which is connected to the underside of the upper partial fleece 11 by way of additional outlet openings 48 formed in the run-up slope 18, which can be designed, for example, as slots, bores or other openings. In addition to or instead of the cavity 49, the interior of the expansion device 16 can be filled with thermal insulation material. Both the upper and lower sides of the expansion device 16 can be coated with thermal insulation material or can be formed from the same. The same applies to the partition 56 laterally delimiting the expansion device 16.

The merging device 17 has a sloping slope 19 in the transport direction 3, and its height is adjustable as it is is indicated by the double arrow 20. Since the lower partial nonwoven 12 guided between the forming line 2 and the underside of the merging device 17 expands in thickness due to the heating by the heating device 13, the friction acting between the partial nonwoven 12 and the underside of the merging device 17 is increased. This friction can be reduced by moving the merging device 17 upwards. The interior of the merging device 17 is also formed as a cavity 50, which is connected to the underside of the upper partial fleece 11 via additional outlet openings 51 formed in the run-off slope 19.

FIG. 2 shows a top view of the device according to FIG. 1, only one half of the device being shown. In principle, the device can be mirror-symmetrical with respect to an axis 47.

From Fig. 2 it can be seen that on the front region 22 of the hollow rail 14 a pipe 23 is provided supply means 24, via which a heat medium from a heat medium storage or generator 25 of the heating chamber 15 can be fed. The supply of the heat medium can be controlled via a valve 26 and a pump 27.

On the top and in Fig. 2 not recognizable also on the underside of the hollow rail 14, a slit-shaped outlet opening 28 is formed, which extends over the entire width of the molding line 2 and the fleece 1, through which the heat medium introduced into the heating chamber 15 emerges and thereby the Partial fleece 1 1, 12 can penetrate. Furthermore, the additional outlet openings 48 and 51 can be seen in FIG. 2, the additional outlet openings 48 being designed as slots and the additional outlet openings 51 being bores, for example. Through the additional outlet openings 48 and 51, additives which are introduced into the cavities 49, 50 via pipelines 52, 53 can be introduced into the partial nonwovens 11, 12.

Furthermore, it is indicated in FIG. 2 by dashed lines 54, 55 that the cavities 49, 50 can also be divided into a plurality of cavities 49 ^' , 49 ^" , 50 ^' , 50 ^" , so that different additives can be introduced into the partial nonwovens. In this case, a corresponding number of different pipes carrying the additives can be provided. The partitions 54, 55 can run perpendicular or horizontal to the transport direction 3 or in any other direction. The direction indicated in FIG. 2 is preferred perpendicular to the transport direction 3 of the fleece, since in this way each of the cavities 49 ^′ , 49 ^″ , 50 ^′ , 50 ^{″ formed} extends over the entire width of the fleece 1 and thus the additives into the whole Fleece 1 can be introduced.

In the front area 22 of the hollow rail 14, a guide and sealing diaphragm 29 is provided, which laterally delimits the fleece 1 and prevents a lateral escape of heat medium from the fleece 1. The guide and sealing diaphragm 29 is formed at its ends on the side facing the fleece 1 in each case obliquely, in particular in a rounded manner, in order to prevent fraying of the lateral edge of the fleece 1. On the top of the hollow rail 14, an elongated guide 30 is formed for a locking slide 31, through which the outlet opening 28 can be closed over a partial area. The locking slide 31 is together with the guide and sealing diaphragm 29 along one

Double arrow 32 slidable, so that the device is adjustable to fleece widths that lie between two maximum and minimum widths indicated by dashed lines 33, 34.

From Fig. 3 and in particular Fig. 4 it can be seen that the hollow rail 14 has a cover plate 35 and a base plate 36, each consisting of two separate sections 35 ', 35 "and 36', 36". The sections 35 'and 35 "or 36' and 36" are each arranged at a short distance from one another, so that the slot-shaped outlet openings 28 are formed between these sections both on the top and on the bottom of the hollow rail 14. In principle, it is also possible for the top and bottom plates 35, 36 to be formed in one piece and for the outlet openings 28 to be designed as bores or as slot-shaped openings which do not extend to the front ends of the top and bottom plates 35, 36.

Furthermore, it can be seen from FIG. 4 that both the upper outlet opening 28 and the lower outlet opening 28 can each be closed over a partial area by a locking slide 31.

The sections 35 'and 36' of the cover plate 35 and the bottom plate 36 are fastened to a common side wall 37, while the sections 35 "and 36" with a common side wall 38 of the hollow rail 14 are connected. This connection can be made using screws or other connecting elements.

On the inside of the side wall 37, an extension 40 comprising a thread 39 is formed, into which a screw 41 guided through the side wall 38 engages. The screw 41 is connected to the side wall 38 in such a way that when the screw 41 is unscrewed from the attachment 40, the side wall 38 and the associated sections 35 "and 36" of the top and bottom plates 35, 36 are displaced such that the width of the outlet openings 28 increases. Correspondingly, the width of the outlet openings 28 can be reduced by screwing in the screw 41.

In order to enable the displacement and thus the width adjustment of the outlet opening 28, air gaps 42 are provided between the lateral outer edges of the top and bottom plates 35, 36 and the widening device 16 or merging device 17 adjoining them.

In the base plate 36 two drain channels 43 are formed which extend over the width of the hollow rail 14 and in which condensate forming in the heating chamber 15 settles and is transported away.

From FIG. 5 it can be seen that the drain channels 43 are connected to a drain opening 44, via which the condensed heat medium can be removed from the heating device 13. Furthermore, it can be seen from FIG. 5 that the locking slides 31 are guided in stuffing boxes 45 made, for example, of Teflon or another suitable material, in order to ensure the tightness of the heating device 13.

Fig. 6 shows that both in the cover plate 35 and in the base plate 36 guides 30 are formed for the locking slide 31, so that both the cover plate 35 and the outlet openings 28 formed in the base plate 36 via the locking slide 31 partially ver - are closable.

Furthermore, FIG. 6 shows the fastening of the cover plate 35, the base plate 36 and the side walls 37, 38 and the expansion and merging devices 16, 17 with a common front side wall 46 via connecting elements, in particular screws 46.

The method according to the invention with the device according to the invention is described in more detail below:

After the fleece 1 has been sprinkled onto the forming line 2 via a spreading device and pre-compressed by means of a pre-pressing unit (not shown), it is transported along the arrow 3 in the direction of the pressing station 5. The moisture of the fleece is approximately 8%.

By running the fleece 1 against the teeth 21 of the endless, revolving saw blade 9 of the band saw 6, the fleece 1 is divided into two substantially equally thick partial fleeces 1 1, 12, which run on of the bevel 18 of the expansion device 16 are separated from one another. Via the pipeline 52, an additive, for example a catalyst for the binder contained in the fleece 1, is passed into the cavity 49 formed within the expansion device 16 and introduced into the partial webs 11, 12 via the additional outlet openings 48.

Heating medium, for example saturated water vapor, is introduced into the heating chamber 15 via both end faces of the hollow rail 14, and exits through the heating openings 15 through the outlet openings 28 formed in the top and bottom plates 35, 36 upwards and downwards Partial fleece 1 1, 12 passes through, so that they are heated. The partial nonwovens 11, 12 are heated to a temperature of up to approximately 80 to 90 ° C., this temperature being reached starting at the respective cut surface of the partial nonwoven 11, 12 up to a position near the respective outer surface. The moisture of the partial nonwovens 11, 12 is, for example, 10% after the heating.

Instead of or in addition to the additive contained in the cavity 49, one or more additives can be introduced into the cavity 50 via the pipeline 53 and introduced into the partial nonwovens 11, 12 via the additional outlet opening 51 after they have been heated. In principle, it is also possible for additives with the heating medium to be introduced into the partial nonwovens 11, 12 via the heating chamber 15 and the outlet opening 28.

After passing the hollow rail 14, the upper partial fleece 11 slides down along the run-off slope 19, so that the two partial fleeces 11, 12 after the end of the merging device 17 come to lie on one another without any interference, since the surfaces of the expansion device 16, the hollow rail 14 and the merging device 17 merge into one another in a substantially fluid manner without any annoying steps.

Subsequently, the two nonwovens 1 1, 12 are pressed in the press station 5 under pressure and renewed heat supply to the desired shaped body. In this case, heat is supplied via the press rolls 4 over the top and bottom of the fleece 1 in the direction of the inside, so that a uniform heat gradient is generated over the entire fleece thickness due to the heat already present in the interior of the fleece 1.

Typical dimensions for the heating device are, for example, one meter in length in the transport direction, the guide and sealing diaphragms typically being of the same length. Instead of the guiding and sealing panels, endless belts that run along for example can also be used, in order to avoid friction on the outer edges of the fleece.

The vapor deposition chamber can have, for example, a cross-sectional area of 60 × 60 mm ² and a width of, for example, approximately 1.20 m to 2.30 m. Depending on the application, these dimensions can also be enlarged or reduced, so that the vapor deposition chamber can have, for example, a cross-sectional area of between 30 x 30 and 200 x 200 mm ² . FIG. 7 shows a variant of a device designed according to the invention similar to the embodiment shown in FIG. 1, so that the same parts have been given the same reference numerals as in FIG.

The exemplary embodiment shown in FIG. 7 differs from the exemplary embodiment shown in FIG. 1 and FIG. 2 in that the heating device 13 is supplied with two separately scattered nonwovens 1 ^' , 1 ^" instead of a uniform nonwoven 1. The supply of the upper separate nonwoven 1 ^" can either manually or by a transport device, not shown, for example an endless conveyor belt.

Basically, the two separate nonwovens 1 ^' , 1 ^"are charged with additives and a heating medium in an analogous manner to the methods described in FIGS. 1 and 2 and, after they have been brought together to form a common nonwoven 1 after passing through the heating device, the pressing station 5 fed to the desired shaped body for pressing.

In order to achieve a simultaneous transport of the separate nonwovens 1 ^' , 1 ^" , the lower separate nonwoven 1 ^' can first be shifted to the press nip formed between the press rolls at the beginning of the process, whereupon the upper separate nonwoven 1 ^" so far over the upper surface of the heater 13 is moved in the direction of the press nip until it is also present on this. Then, for example, the two press rolls 4 can be set in rotation, so that the two front ends of the separate fleeces 1 ^' , 1 ^"are gripped and evenly pulled together as a uniform fleece in the press nip. At this point in time or even beforehand, the heating medium and the additives can be supplied so that the two separate nonwovens 1 ^' , 1 ^" are penetrated both by the heating medium and by the additives.

Claims

claims

1. A process for the production of moldings, in particular of fiber, particle board or the like, in which fibers, cellulose or lignocellulose-containing particles mixed with binder form one

Fleece (1) are scattered and preheated before the fleece (1) is pressed to the shaped body with the supply of heat and pressure, characterized in that the preheating of the fleece consisting of the pre-compressed or pre-pressed fibers or similar particles (1 ) by supplying thermal energy from the inside of the fleece (1) to the outside towards the surface of the fleece.

2. The method according to claim 1, characterized in that at least one additive, in particular a catalyst for the binder contained in the fleece (1), also from the inside of the fleece (1) outwards to the surface of the fleece (1) into the fleece (1) is introduced, and / or that the preheating is carried out by supplying a heated, in particular fluid heating medium, advantageously in the form of hot air, saturated or superheated steam.

3. The method according to claim 1 or 2, characterized in that to form the fleece (1) first two separate fleeces (1 ', 1 ") are scattered, pre-compressed or pre-pressed, which are each brought together so that the facing each other Sides of the

Nonwovens (1 ', 1 ") form the inside and the sides of the nonwovens (l ¹ , 1") facing away from one another form the upper and lower sides of the nonwoven (1).

4. The method according to claim 3, characterized in that the supply of the thermal energy and optionally the introduction of the additives takes place in particular immediately before the merging of the nonwovens (1 ', 1 ").

5. The method according to claim 1 or 2, characterized in that the fleece (1) has a mat-shaped structure, is cut open substantially parallel to its top and bottom and the heat and optionally the introduction of the additive through the cut surfaces both in the direction to the top and to the bottom of the fleece (1).

6. The method according to any one of claims 2 to 5, characterized in that the introduction of the additives into the fleece (1) is carried out by spraying.

7. The method according to any one of claims 2 to 6, characterized in that the additive is introduced in dissolved form as a fluid, in particular in liquid form, into the fleece (1).

8. The method according to any one of claims 2 to 7, characterized in that the additive is introduced into the fleece (1) before and / or simultaneously with and / or after preheating the fleece (1).

9. The method according to any one of claims 2 to 8, characterized in that as additives hardener, in particular ammonium chloride, ammonium sulfate, ammonium nitrate and / or hexamethylene tramine, and / or formic acid, maleic acid, citric acid, sulfuric acid, hydrochloric acid, aluminum sulfate (chloride), persulfate , Phosphoric acid; and / or water repellents, such as paraffin; and / or wood preservatives, fungicides; and / or fire retardants; and / or formaldehyde scavengers, such as urea; and / or extenders; and / or dyes are used.

10. The method according to any one of the preceding claims, characterized in that the fleece (1) is pre-pressed before the preheating and / or before the introduction of the additive.

11. Device for the production of moldings, in particular fiber, chipboard or similar panels, in particular for carrying out the method according to one of the preceding claims, with a scattering station, a molding line (2), a press station (5) and one of the press station ( 5) upstream heating device (13) for heating a fleece (1) scattered from the spreading station onto the molding line (2) before it enters the pressing station (5), characterized in that the heating device (13) for supplying heat from the inside of the fleece (1) is formed on the outside towards the surface of the fleece (1).

12. The apparatus according to claim 11, characterized in that the heating device (13) for introducing additives, in particular a catalyst for the binder contained in the fleece (1), into the fleece (1) also from the inside of the fleece (1) after is formed on the outside towards the surface of the fleece (1).

13. The apparatus of claim 11 or 12, characterized in that a separating device designed in particular as a cutting device (6) is provided, with which the fleece (1) can be divided into at least two, in particular into a lower and an upper partial fleece (11, 12) and that the heating device (13) is arranged in the area between the partial fleeces (11, 12).

14. The apparatus according to claim 13, characterized in that the separating device is designed as a saw (6), in particular as a band saw, preferably as an endless band saw.

15. Device according to claim 13 or 14, characterized in that the cutting direction of the cutting device (6) is directed against the transport direction of the fleece (1) essentially parallel to the surface of the molding line (2).

16. The device according to one of claims 13 to 15, characterized in that the separating device (6) is arranged in front of the heating device (13) in the transport direction of the fleece (1).

17. The device according to one of claims 11 to 16, characterized in that the heating device (13) comprises a heating chamber (15) which extends substantially over the entire width of the nonwoven (1) and which in its partial fleeces (11, 12) facing areas, in particular slit-shaped outlet openings (28) for discharging heating medium, in particular steam, from the heating chamber (15) into the fleece (1) and, if appropriate, additional outlet openings (48, 51) for introducing the additives into the fleece ( 1).

18. The apparatus according to claim 17, characterized in that the outlet openings (28) are at least partially closable, in particular via a locking slide (31).

19. The apparatus according to claim 17 or 18, characterized in that the outlet openings (28) are adjustable in size.

20. Device according to one of claims 17 to 19, characterized in that the heating chamber (15) comprises at least one lateral, in particular outside of the fleece (1) located feed device (24) for supplying the heating medium.

21. Device according to one of claims 17 to 20, characterized in that supply devices (24) for supplying heating medium are provided on both end faces of the heating chamber (15).

22. Device according to one of claims 17 to 21, characterized in that an expansion device (16), in particular with an inclined slope (18), is arranged in the transport direction in front of the heating chamber (15) for widening the distance between the partial fleeces (11, 12) , and that, if necessary, the additional outlet openings (48) are formed in the expansion device, in particular in the run-up slope (18).

23. Device according to one of claims 17 to 22, characterized in that in the direction of transport behind the heating chamber (15) a merging device (17), in particular with a slope (19), for evenly merging the partial nonwovens (11, 12) to form a total nonwoven and that, if necessary, the additional outlet openings (51) are formed in the merging device, in particular in the run-off slope (19).

24. Device according to one of claims 17 to 23, characterized in that the outlet openings (28) simultaneously form the additional outlet openings (48, 51).

25. Device according to one of claims 22 to 24, characterized in that the expansion device (16) and / or the merging device (17) several, in particular completely separated from one another, preferably as cavities (49 ', 49', 50 ', 50th ") includes trained sections.

26. Device according to one of claims 11 to 25, characterized in that at least one limiting unit impermeable to the heating medium, in particular in the form of a guide and sealing diaphragm (29), is provided on the side of the fleece (1) in the region of the heating device (13) .

27. The device according to claim 26, characterized in that the limiting unit is designed to be displaceable in particular together with the locking slide (31).

28. Heating device for preheating a fleece with the features of claims 11 to 27 relating to the heating device (13).