EP1938935A2 - Prepress for pre-compactage and deairing of a pressed material mat in the course of material plate production - Google Patents

Abstract

The pre-press (1) has a continuously circulating driven venting belt (2) above the pressed material mat (9) circulating on a molded belt (6), whereby the molded belt and the venting belt are supported and subjected to pressure by compression rollers (5) and/or supporting rollers (16). At least two driven drive rollers (7) are arranged in the main compression region (12) of the pre-press for tensioning and driving the molded belt.

Description

The invention relates to a pre-press for precompression and deaeration of a pressed material in the course of the production of material plates according to the preamble of claim 1. Under material plates, the invention MDF, OSB, fiber or particle board and mixed products not only cellulosic material, but also other aggregates or Contain fillers such as plastics or foams.

Such a method and apparatus of which the invention is based is known from DE 27 28 660 A1 already known. Accordingly, a scattered Pressgutmatte to be deaerated and compacted immediately after molding. Immediately thereafter, the pre-compacted pressed material mat is compacted in a compacting unit, usually a continuously operating double belt press or a calender press, by means of pressure and heat to form a material plate and cured. The pre-press used here consists of a belt for venting, which runs endlessly underneath the pressed material mat and a fixed endless endless belt arranged above the press material mat. The venting belt is pulled over a table up to a pressure roller and the upper solid belt is supported by rollers.
The industry has been open to the continuous process for the production of material panels for years and it has already published a variety of patent and non-patent literature for such processes. In addition to an active pre-compression by means of suction of the pressed material mat, other process variants have become known which play a role in the pre-compression. For example, it is from the DE 44 41 017 A1 Not only does the press material mat during the pre-compression vent, but also with process gases to flood, such as superheated steam or superheated steam. Such influences on the thermal and other properties of the pressed material mat are intended to positively influence and improve the pressing factor and thus the possible production quantity of the continuous production process.
Although the design effort of the above pre-press has been proven in practice, it is now no longer necessary to intervene in the structure and in the parameters of a scattered Pressgutmatte in most industrial manufacturing processes for material boards, since the process parameters for the compression and curing already can be adjusted to the forming belt with maximum efficiency in the processes before the dispersion of the material to be pressed. Such parameters are for Example moisture and particle size of the material to be pressed or type and amount of the binder.

In the present time, the task of the pre-press is to ensure the smoothest possible process flow with few production-related disturbances. At the same time, in addition to low wear of the endless or endless conveyor and compacting belts used, it should also be possible to use high pressures during prepressing. Since each machine element in a large manufacturing plant next to the production costs and eventually produces maintenance costs, it is a compelling competitive advantage for the manufacturer and also for the later operator of a manufacturing plant, if by omitting expensive machine elements with high maintenance costs and simultaneous replacement with comparatively cheap machine elements with low Maintenance costs and possibly even better stability of the same production operation maintained or even improved and downtime due to disruption and maintenance can be reduced. In conventional pre-pressing between a scattering station and a continuously operating press for venting and pre-compression several variants are in use. The main difference of the variants is whether the forming belt, on which the pressed material mat is scattered, reaches almost to the continuously operating press and runs through a pre-press or whether the forming belt is used only for the production (shaping) of the press-mat and these then passes to a bottom circumferential compression belt for transport through the pre-press. As a rule, the application is determined by whether the pressed material mat is to be vented on both sides (top and bottom) or only on one side (top) during compression. Both variants have in common that they need a lower circulation for a compression belt with or without form band support in the pre-press. In systems in which only one-sided venting during pre-compression is considered sufficient, it is advantageous if one waives a lower compression band and the forming belt, which passes through the pre-press, thus simultaneously assumes the tasks of the compression belt.
In principle, however, there is the need to support the forming belt in the pre-press by another compression belt, as a forming belt is usually not able to withstand the necessary belt tensions that brings the compression process in a pre-press with it. If precompressed in a conventional pre-press without a lower circumferential compression belt (also called support belt), even with a narrow support distance of the support rollers the pressed material mat is driven, as it comes to buckling of the forming belt between the support rollers. At the same time caused by the bulges and the associated stress peaks massive swelling loads that can lead to plastic deformation of the forming belt, which significantly reduces the stability. It comes thus over time to spontaneous failure or permanent load breaks in the form band. An obvious solution to the problem by increased execution of the forming belt is due to the small bending radius of the transfer roller shortly before the continuous press not into consideration. These pulleys need for the closest possible transfer point of Pressgutmatte to the lower steel strip of a continuously operating press the smallest possible deflection roller, which defines the nature and strength of the forming belt and the bearable belt tension is limited.
Added to the problem of reduced stability is that it can cause damage to the pressed material mat in a strong bulging of the forming belt. Such structural changes in the press mat appear on the final product surface as small cracks or may have an unfavorable effect on the bending and transverse tensile strength and thus give an undesirable notch effect in the created material plate structure.

This results in both described variants of the execution of a pre-press the need to establish a lower belt circulation of a compression belt (with or without forming belt), which is associated with manufacturing costs and maintenance costs.

Also, the obvious solution between pre-press and continuously operating press to arrange their own transfer belt to make the pulleys of the forming belt larger, takes only limited. Because Again, a separate transfer belt circulation is required, with corresponding costs. Even with a positive cost / benefit analysis of possible constructive solutions to allow the use of a reinforced form band, at the latest the negative portion of the cost of a form band reinforcement is so strong that such solutions do not pay off. A forming belt in large systems can be up to 100 m in length. For example, 30 m spreading area, 10 m pre-press, and 10 m unused transport length in intermediate areas of a plant are not uncommon.

The currently suitable and available ventilation belts have a maximum tensile stress of 25 N / mm as the operating voltage, so that it can be compressed with sufficient pressures. In order to provide appropriate pressures for compaction, the compaction rollers must have a minimum diameter of 200 mm. But this results in a high support distance in the main compression region of a pre-press at maximum compression force, which can lead to a wave-like compression pattern (walking) of the pressed material mat.

Due to the wide support distances of more than 200 mm, the pressed material mat presses a circulating belt, which is tensioned to a value of less than 25 N / mm, between the compaction rollers up to the subsequent compacting roller at the radius of the roller is guided against the pressed material to compact this. Especially in the area of the strongest compaction of the pressed material mat, this leads to excessive loads and wear of the forming belt.

To make matters worse, that the belt tension can not be arbitrarily increased in a lower mold belt, because mold belts can be applied usually only with a belt tension of less than 10 to 15 N / mm. Forming belts are usually assembled in the production plant on site to form an endless belt and thus contain joints of weak quality. Next, the space in the scattering rarely allows a complex design of the Formbandförderanlage and therefore can not be designed to take up high tape tensions too expensive.

The invention is an object of the invention to provide a pre-press, in which the plant technical complexity is reduced compared to the prior art, while allowing high compression pressures to act on the Pressgutmatte. Next, the forming belt in the main compression area of a pre-press should be supported in such a way that no harmful flexing movements occur and a complete venting of the pressed material mat according to the predetermined parameters is possible.

The solution to this stated problem consists in the provision of a pre-press, which is characterized in that at least two driven drive rollers are arranged in the main compression region of the pre-press for clamping and driving the forming belt.

In the proposed prepress, in a forming belt in the main compression region, almost no deflection occurs during compaction. This is done by arranging at least two driven compaction rollers in the main compaction area that pull and retighten the forming belt through this area. Due to the additionally applied tensile forces (in the direction of production in front of the respective drive roller) in the forming belt this is kept stretched and can not bulge, even if the belt tension of the forming belt, which is generated in the return area, very low, for example, below 15 N / mm , preferably 5 N / mm, is. The belt tension of the forming belt, which is generated in the return, is used up to a large extent by the rollers in the inlet region of the pre-press during the compression. Due to the advantageous arrangement by at least two, preferably by three, driven drive rollers in the main press area significantly higher precompression forces can be introduced into the pressed material mat. In the process, neither the taut bleeding belt nor the tensioned stretched belt is deflected. Also, by the arrangement of the venting band at the top without an additional support band the pressed material mat on the entire Length of the pre-press are vented, whereby the opposing forces are reduced, because the air can escape through the short path perpendicular to the Pressgutmattenoberfläche and is not included. Simplified and continuous venting via the pressed material mat surface sides minimizes backpressure from the pressed material mat during precompression. With a support band closed at the top, the air would have to escape through the narrow surfaces of the pressed material mat. With the pre-press according to the invention, a balancing out of the venting belt does not take place, since the belt tension in the venting belt can be set above 15 N / mm, preferably 25 N / mm, without the service life of the venting belt being reduced or the forming belt also being warped. The lifetime is not reduced because the diameter of the deflection and drive rollers are greater than 100 mm.

Further advantageous measures and embodiments of the subject matter of the invention will become apparent from the dependent claims and the following description with the drawing.

The drawing shows a schematic view of the structure of a production plant for the production of material plates in the range of a spreader 10 to the beginning of a continuously operating press 20 with pre-press arranged therebetween 1. The forming belt 6 undermines it after the return to produce a pressed material 9 spreader 10 passes through the pre-compression for pre-compression and passes, preferably directly, the compacted pressed material 9 to the continuously operating press 1. The forming belt 6 is guided over pulleys 14 and has in the transfer area to the continuously operating press 20 a transfer roller 22 with a small diameter in order to pass the press material mat 9 as close as possible and at a short distance to the lower steel strip 17 of the continuously operating press 1. In a system variant, not shown, a device for dropping defective or improperly scattered Pressgutmatten may be provided at the end of the forming belt. The pressed material mat is transferred with the device closed to a transfer belt and from there to the continuously operating press 1 or falls when the device is open in a discharge bunker (not shown) and is broken there and recycled.
The continuously operating press 1 is embodied in the exemplary embodiment as a double-belt circulating press, which has two endlessly guided steel belts 17 at the top and bottom, which are guided around deflecting drums 18 in the press inlet or press outlet. For the transmission of temperature and pressure 17 heating plates 19 are arranged between the steel strips, which are usually supported with a sliding roll bar carpet against the steel strips 17. In further possible embodiments, the forming belt 6 can also transfer the precompressed press material mat 9 to a continuous calender press or to a cycle press. During transport of the Pressgutmatte 9, the forming belt 6 through Transport rollers 13, supported in the pre-press 1 by support rollers 16. In principle, the additional or alternative application of support tables 26 is conceivable which are arranged in a preferred embodiment below the mold belt 6 spaced. The distance here is about 10 mm to support in case of bulging of the forming belt. At the same time the distance reduces the friction and prevents damage to the forming belt 6, since the compressive forces of the forming belt 6 perpendicular to the support table 26 and thus also the Reibugnskräfte parallel to the forming belt 6 are not very large. In the main compression region 12 of the compression region 11 of the pre-press 1 at least two driven by drives 8 drive rollers 7 are provided. Preferably, at least three driven drive rollers 7 are provided, wherein the drive rollers 7 are driven either via a common drive 8 or synchronized drives 8. In order to transfer the driving forces of the drive rollers 7 better to the forming belt 6, the drive rollers 7 preferably have suitable surfaces, such as corrugated or ribbed, or coatings (for example, a rubber coating) to improve the coefficient of friction. In the production direction 21, in a preferred embodiment, sensors 23 for the belt tension are arranged in front of each and / or only on a drive roller 7, which measure the introduced driving forces in a control loop and regulate at high belt tensions via a control and regulating device 24 on the drives 8 intervene. The drives can do this 8 may be arranged mechanically or electronically connected in the same way or be controllable via individual NC-controlled drives. Not shown is the actual main drive of the forming belt 6, which is arranged according to the requirements or according to the respective plant-specific possibility. The upper circulation of the venting belt 2 is carried out conventionally in its manner, wherein the venting belt is driven via a drive roller 3 in the outlet of the pre-press 1 and is guided over deflection rollers 15. The feed roller 4 of the pre-press, which is also designed as a circulation roller, is arranged in a height-adjustable manner by means of hydraulic actuators (not shown) and can adjust the compaction angle of the just-spread pressed material mat 9 relative to the forming belt 6. The following compaction rollers 5 are adjusted according to the employment of the inlet roller 4 to ensure optimum compression and ventilation in the inlet region of the pre-press 1 through the venting belt 2. In a further preferred embodiment, a control device 25 for checking for wear or damage of the forming belt 6 is arranged in the return of the forming belt 6. The pressurized rolls in the region of the pre-press 1 can be provided with a camber for optimum setting of the precompression gap between the forming belt 6 and the venting belt 2. This means that the drive rollers 7 and / or the support rollers 16 and / or the compaction rollers 5 have a thickening in the middle over the width of the pressed product mat 9 in order to compensate for the deflection of the individual roller in the application of the compression forces. It has the

Diameter of the rolls in the middle seen across the width 1 to 3 mm more than the diameter at the edge of a roll.

The drive drum 3 in the upper belt circulation is arranged opposite to the last compression roller 5 so that the pressed material mat 9 is gently relieved after the main compression region 12, because the pressed material mat 9 springs back after each pre-compression again an elastic portion. If the pressed material mat 9 is relieved too quickly or even suddenly without additional support after the pre-press 1, this can lead to cracks or structural inhomogeneity, in particular in the case of thick press material mats 9. The belt tension of the venting belt 2 is adjusted and regulated by actuators 27 articulated to the adjusting roller 32, for example hydraulic or pneumatic piston-cylinder arrangements. Here, at the same time a band progression control can be performed, since the total length of the circulating venting band is relatively low. Further, in the tape return to the drive roller 3, a mechanical belt cleaning device 28, for example, designed as a rotating brush roller arranged. Alternatively or additionally, a pneumatic belt cleaning device 29, for example a blow bar, may be arranged. A mechanical belt cleaning device 28 is also in the lower band circulation of the forming belt 6 in the return, as soon as possible after the transfer roller 22 so as not to unnecessarily transport dirt (sticking pressed material) or scattered over the entire length of the return. Because the It is obvious that, for example, between the steel strips 17, which usually revolve at a high temperature, and the forming belt 6, an insulating wall (not shown) is arranged. This also serves to prevent unwanted material transfers from the forming belt 6 on the lower steel strip 17 after the transfer roller 22 in the return. The primary belt tension of the rotating forming belt 6 is otherwise ensured in the return by a vertically adjustable tension roller 31. Also in the return is the belt control device 30, which prevents a course of the forming belt 6 or sets an optimal tape run of the forming belt 6.

In an expanded embodiment, not shown, also the upper venting band in the main compression region has at least two, preferably three, driven support rollers or drive rollers.

List of Reference Numerals: DP 1336 EP

1.

pre-press

Second

ventilation Belts

Third

drive roller

4th

inlet roller

5th

Compression rollers above

6th

forming belt

7th

drive rollers

8th.

drives

9th

press material mat

10th

spreader

11th

compression region

12th

Main compression region

13th

transport wheels

14th

Deflection rollers below

15th

Guide rollers above

16th

Back up rollers

17th

steel strips

18th

idlers

19th

Hot Plates

20th

continuously working press

21st

production direction

22nd

Transfer roller

23rd

sensor

24th

control device

25th

control device

26th

supporting table

27th

actuators

28th

Belt cleaning device
(mechanically)

29th

Belt cleaning device
(pneumatic)

30th

Band control device

31st

tension roller

Claims (8)

Prepress (1) for pre-compression and deaeration of a pressed material mat (9) of chips, fibers, particles or the like scattered on an endlessly circulating forming belt (6) in the course of the production of material plates by pressing the pressed material mat (9) in a main press (20 )
wherein in the pre-press (1) above the on the forming belt (6) passing through the press material mat (9) an endlessly circulating and driven venting belt (2) is arranged, and
wherein the forming belt (6) and the venting belt (2) are supported and pressurized by a plurality of compaction rollers (5) or support rollers (16) arranged parallel to one another and transversely to the production direction (21) of the press material mat (9), characterized in that at least two driven drive rollers (7) are arranged in the main compression region (12) of the pre-press (1) for clamping and driving the forming belt (6). Prepress according to claim 1, characterized in that at least three drive rollers (6) are arranged side by side to drive the forming belt (6). Prepress according to claim 1 or 2, characterized in that for driving the forming belt (6) at least three drive rollers (7) by means of at least one drive (8) are arranged mechanically or electronically connected in parallel. Prepress according to one of Claims 1 to 3, characterized in that sensors (23) for monitoring the belt tension of the forming belt (6) are arranged to control the driving force by the drives (8). Prepress according to one of claims 1 to 4, characterized in that in the return of the forming belt (6) a control device (25) for checking for wear or damage of the forming belt (6) is arranged. Prepress according to one of claims 1 to 5, characterized in that the drive rollers (7) have a suitable profiling or a coating for improving the transmission of the forces of the drive (8) on the forming belt (6). Prepress according to one of claims 1 to 6, characterized in that the drive rollers (7) and / or the support rollers (16) and / or the compaction rollers (5) have a camber. Prepress according to one of claims 1 to 6, characterized in that below the forming belt, a support table (26) is arranged at a distance

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