WO2006084498A1

WO2006084498A1 - Method and device for the production of insulation sheets

Info

Publication number: WO2006084498A1
Application number: PCT/EP2005/013192
Authority: WO
Inventors: Michael Hoppe
Original assignee: Grenzebach Bsh Gmbh
Priority date: 2005-02-14
Filing date: 2005-12-09
Publication date: 2006-08-17
Also published as: EP1851022A1; DE502005011013D1; EP1851022B1; DE102005006796B3; ATE499193T1

Abstract

On production of insulation sheets, care must be taken to ensure the velocity of the processing gas remains low, as otherwise mixing within the still unhardened fibres or thickness differences can occur. The devices must be correspondingly large. According to the invention, said disadvantage is overcome, whereby the shaping of the fibres occurs in two stages (7, 8), each stage (7, 8) comprising gauging and fixing and the upper surface of the partly fixed fibres are smoothed between stages (7, 8).

Description

Method and device for producing insulation boards

The invention relates to a method for producing insulating panels of fibers according to the preamble of claim 1 and to an apparatus for carrying out the method. From DE 196 35 410 A1 a method for the production of insulation boards is known in which wood and / or plant particles are machined into a raw material and then glued and dried. From the intermediate material thus obtained, a non-woven is formed by scattering, which is compacted to a desired plate thickness and treated for 10 to 20 seconds with a vapor-air mixture. Care is taken here to avoid pre-curing of the binder. Finally, a hot air stream is passed through the compacted web to dry it and cure the binders.

WO 02/22331 describes a process for the production of plate-shaped form elements based on natural fibers, in which natural fibers are mixed with binders and then applied to a forming station. Here, the mixture is molded and steamed, whereby it is solidified. Subsequently, the mixture is pressed, and there is a Heißluftaktivierug the binder.

These known methods are one-step, that is, the fiber-binder mixture is calibrated once, and then the binders are activated and / or cured. This has the disadvantage that the speed of the gas for activation and / or curing must be low so that the loose structure of the mixture is maintained and no surface unevenness occurs. On the other hand, the maximum temperature of the gas is limited by the material of the fibers and the binder, so that an improvement in productivity by increasing the temperature is not possible. Therefore, an apparatus for producing insulating panels must be made relatively large so that the effectiveness of the binder is fully achieved and, where appropriate, undesirable moisture can be evaporated.

Fibers in the context of this invention are all fibrous materials suitable for making insulation boards, such as glass wool, rockwool, plastic fibers, wood fibers, paper fibers, flax, wool and cotton, singly or mixed. The term binder comprises a single suitable substance or a mixture of several substances. Suitable substances are liquid, powdery or fibrous and consist for example of resin or plastic. The object of the invention is to provide a method for producing insulating panels made of fibers, can be driven in the case of larger amounts of air and in which a device can be designed correspondingly smaller. Another object is to provide a device for carrying out the method. The first object is solved by the features of claim 1. The molding of the insulation boards is divided into two stages. Each of the stages comprises calibrating and fixing a fiber-binder mixture, wherein the height of the mixture in the first of the stages is greater than in the second. In each of the stages, a suitable gas, eg heated air, is passed through the mixture from top to bottom to fix the binders. Here, the first stage is designed so that the binders are only partially effective. These measures cause the fixing in each of the stages can be done with a larger amount of air, whereby they can be dimensioned much smaller than the known devices or have a correspondingly higher capacity.

The greater amount of air in the first stage caused due to the higher flow rate in conjunction with only incomplete fixation that eg short fibers entrained and / or very loose parts of the mixture (with relatively little mass per volume) are compressed. In this way, the upper surface of the web in the first stage can be uneven, that is, it can be indentations on the surface. These bumps are compensated by the smoothing, which is carried out between the stages, and ^"by the second calibration, so that an insulation mat with the required characteristics is available at the end of the process.

The same applies to the second object, which is solved by the features of claim 7.

The subclaims relate to the advantageous embodiment of the invention. Milling according to claim 2 causes protruding material is removed from the surface and entered into the recesses. As a result, the finished insulation board is generally homogeneous and their surface smoother.

The thickness ratios according to claim 3 provide a structure of the mixture which is well permeable to air and therefore allows a high speed of the heat treatment agent in the mixture, without the structure of the finished insulating panels is adversely affected. This is to be seen in particular in connection with the speed range according to claim 4 for the heat treatment agent. The temperature according to claim 5 and the residence time according to claim 6 ensure the full function of the binder and optionally the drying of the mixture by utilizing the best possible performance, without damaging the fibers and / or the binder. The invention will be further explained with reference to the embodiment shown schematically in the drawing. Show it

1 shows a longitudinal section through a device according to the invention and Figure 2 shows an alternative smoothing device.

As can be seen from FIG. 1, a device for producing insulating panels comprises a horizontal, endless conveyor belt 1, which is guided on the input side, in the figure, on the left and on the outlet side, around a respective deflection roller 2. One of the guide rollers 2 is connected to a drive.

Arranged above the input-side end of the conveyor belt 1 is a spreading device 3 for a fiber-binder mixture, which is connected to a mixing station (not shown). Under the spreader 3 adjustable strips 4 are attached to limit the width of the insulating panels directly above the belt.

In the transport direction according to arrow 5, to which directional data refer in the following, behind the scattering device 3, a housing 6 is arranged so that it encloses the conveyor belt 1 in a region between the guide rollers 2. Within the housing 6, two stages 7, 8 are arranged for forming the insulating panels. Each of the stages 7, 8 comprises an endless Kalibrierband 9, 11, which is parallel to the conveyor belt 1 or alternatively wedge-shaped and guided around rollers 10, 12. Furthermore, means (not shown) for circulating a heat treatment agent, eg heated air, are arranged for each stage 7, 8. The first stage 7 begins immediately behind the entrance of the housing 6 and ends shortly before the center of the housing 6. The length of the first stage 7 is 5 to 50% of the length of the housing 6. The distance of a first lower run 9a of the first 9 Kalibrierbands Upper strand 1a of the conveyor belt 1 is adjustable over the first rollers 10. One of the first rollers 10 is connected to a drive. The second stage 9 begins shortly behind the center of the housing 6 and ends at the outlet of the housing 6. The length of the second stage 9 is 40 to 95% of the length of the housing 6. The distance of a second lower run 11 a of the first Kalibrierbands 11 to the upper strand 1 a of the conveyor belt 1 is adjustable via the second rollers 12. One of the second rollers 12 is connected to a drive.

Between the Kalibrierbändern 9, 11, a smoothing device in the form of a smoothing roller 13 is arranged vertically adjustable over the width of the conveyor belt 1. The smoothing roller 13 is connected to a drive. She has a roughened coat; alternatively, e.g. Sprockets or radially projecting pins distributed over the shell arranged. The smoothing device extends over 0 to 10% of the length of the housing 6.

If required, a cooling device and furthermore a cutting device are arranged behind the rear deflecting roller 2 (not shown). The conveyor belt 1 and the calibration belts 9, 11 are permeable to air and e.g. designed as a screen belts. They have an at least approximately the same width.

In operation, fibers are mixed in the mixing station and as binder plastic fibers in a suitable ratio to the fiber-binder mixture and conveyed continuously to the scattering device 3. This scatters the mixture largely uniformly on the continuous conveyor belt 1, so that a nonwoven fabric with preselectable basis weight arises. The spread corresponds approximately to the desired width of the insulation boards; whose width is further determined by the strips 4.

The fleece is transported in the direction of the arrow 5 in the housing 6 and thus in the first stage 7 and precompressed by means of the first Kalibrierbands 9 to a first thickness. The first thickness corresponds to the 0.8 to 2.0-folds, in particular the 1, 1 to 1, 6-folds of the desired thickness of the insulating panels. The first calibration belt 9 is driven at a speed approximately the same as the conveyor belt 1 so that the first lower run 9a runs in the same direction as the web. In the first stage 7, the precompressed web is flowed through by heated air from top to bottom and in this way partially solidified by the binder is partially activated. The air has a relatively high speed in comparison with the known methods, so that irregularities in the form of indentations may occur on the upper surface of the nonwoven.

These irregularities are compensated by the smoothing roll 13, by these fibers from the higher places of the upper surface removes and stores in the indentations. For this purpose, the smoothing roller 13 is driven in the same direction with the transport direction of the web. Alternatively, the smoothing roller 13 is driven in opposite directions. The height of the smoothing roller 13 is set so that its lowest boundary between the height position of the first lower run 9a and the second lower run 11a is arranged. The distance of the lowest boundary to the upper strand 1a of the conveyor belt 1 is 0.9 to 1, 9 times, in particular the 1, 2 to 1, 6 times the desired thickness of the insulating panels.

After the smoothing roller 13, the precompressed nonwoven enters the second stage 8, where it is compressed plates with the aid of the second Kalibrierbandes 11 to the desired thickness of the insulating material and is flowed through by heated air from top to bottom. In this case, the binder is fully activated. Even in the second stage 8 relatively high air velocities are adjustable, without causing disadvantages, because the web was already preconsolidated in the first stage 7.

In both stages 7, 8, the air is circulated in a known manner. For this purpose, for each stage 7, 8, the air is sucked out of a space below the upper run 1a through a fan, heated after the blower in a heat exchanger and further passed through nozzle boxes on the surface of the web.

After solidification, the web can be cooled before being cut into sheets in a cutter. The operating conditions for the production depend on the mixture used and the desired thickness of the insulating panels. In both stages 7, 8, the air velocity through the web is 0.1 to 1.5 m / s. The residence time in each stage 7, 8 is 1 to 10 min, based on the thickness of the insulating panels in particular 0.25 to 0.75 min / 10mm. The temperature of the heated air is greater than 100 ⁰ C, in particular 130 ° to 16O ⁰ C. The pressure difference of the air between the space above and the space below the web is up to 180 mmWS, preferably 30 to 100 mmWS.

The finished insulation boards have a thickness of 5 to 200 mm.

In an alternative embodiment of Figure 2, a plate 14 is arranged as a smoothing device. It is inclined in the transport direction falling. The surface of the sheet metal 14 facing the conveyor belt 1 is rough and / or provided with short pins. The sheet metal can be connected to a drive, which oscillates it during operation.

Claims

claims

A process for the continuous production of insulating panels of fibers, wherein the fibers are mixed with a binder, wherein the mixture of fibers and binder in a predetermined thickness on a carrier tape (1) applied to a nonwoven, then calibrated to a desired thickness and then a heat treatment is fixed and optionally dried, characterized in that the shaping takes place in two stages (7, 8), wherein each of the stages (7, 8) comprises calibrating and fixing, and that the upper surface of the partially fixed nonwoven fabric between the stages (7, 8) is smoothed.

2. The method according to claim 1, characterized in that is milled for smoothing.

3. The method of claim 1 or 2, characterized in that a thickness of the web after the first calibration 0.8 to 2.0 times a desired thickness and after smoothing the 0.9 to 1, 9 times the Target thickness of the insulation boards is.

4. The method according to any one of claims 1 to 3, characterized in that a speed of the heat treatment agent by the applied mixture is 0.1 to 1, 5 m / s.

5. The method according to any one of claims 1 to 4, characterized in that a temperature of a heat treatment agent is 100 ° to 180 ⁰ C.

6. The method according to any one of claims 1 to 5, characterized in that a residence time in each stage (7, 8) 0.25 to 0.75 minutes per cm target thickness.

7. An apparatus for the continuous production of insulating panels made of fibers with a drivable conveyor belt (1), with a Aufrereuvorrichtung (3) which distributes a mixture of the fibers and a binder on the conveyor belt (1) to a non-woven, with at least one Kalibrierband (9, 11), which is arranged above the conveyor belt (1) and with means for blowing heated gas through the calibrated nonwoven, wherein the gas is at least partially recirculated, characterized in that two calibration belts (9, 11) arranged in the transport direction one behind the other, wherein the distance between a first of the Kalibrierbänder

(9) and the conveyor belt (1) is greater than the distance between a second of the Kalibrierbänder (11) and the conveyor belt (1), and that between the Kalibrierbändern (9, 11) is arranged a smoothing device.

8. Apparatus according to claim 7, characterized in that the smoothing device is a roller (13).

9. Apparatus according to claim 7, characterized in that the smoothing device is a metal sheet (14).