DE1759511B2 - METHOD AND DEVICE FOR MANUFACTURING THERMAL INSULATING PLATES OR MOLDED PIECES FROM MINERAL FIBERS WITH EMBEDDED NON-DEFORMABLE PARTICLES - Google Patents

Description

The invention relates to a method for producing heat-insulating plates or molded pieces Mineral fibers, in particular made of glass fibers, in which the mineral fibers immediately after their production as

ν fiber flow are moved downwards, while the downward movement the fiber flow is not deformable Particles are supplied and a thermosetting binder is sprayed onto the fibers and / or particles is put down and the binder is hardened

s ^ will.

The invention also relates to an apparatus for carrying out the method or for producing heat-insulating plates or shaped pieces made of mineral fibers, in particular glass fibers, with a

'«Fiber manufacturing facility for energizing a down moving fiber stream, with below the fiber distribution device in the vicinity of the generated fiber stream arranged feed devices for introducing non-deformable particles

'' - in the fiber stream, with an endless conveyor belt for Receipt of the fiber-particle mixture and with a suction device arranged below the conveyor belt.

This method and this device are known _; ewritten by OE-PS 2 41717. According to this patent specification, the particles fed to the fiber stream serve to give the product an increased temperature resistance. The particles are therefore of an appropriate quality. The particles are fed in by means of nozzles, from which the particles emerge in atomized form and are blown into the fiber stream.

* With the invention, however, a different goal is pursued. The products in question here should, on the one hand, have a high level of insulation (sound and heat) and, on the other hand, have great dimensional stability. It has been established through experiments that the measures according to the Austrian patent specification are insufficient to produce such a product with satisfactory properties. On the one hand, the desired dimensional stability is not achieved. On the other hand, inclines the measures in accordance with the Austrian Patent Specification product obtained to that in _b eschleuderten into the fiber stream particles trickle out part of the finished product again.

Through the DT-PS 10 03 563 a suspension of inorganic fibers with admixture of Fillers became known. But such a bloating cannot be compared with that Supply of solid particles in order to improve the measures according to the OE-PS 241 717.

Due to the DT-AS 11 31 587 a fiber material is made Glass fibers become known in which a powdery substance is distributed. According to this However, a large dimensional stability is not aimed for in the interpretation document. It is also said in this document that it is important that the particles are uniformly distributed throughout the fiber material. But it is nothing tells how this even distribution can be brought about. Even the one in this one Measures disclosed in the interpretative document are therefore not suitable for improving the measures to serve the OE-PS2 41 717.

From the known patent application A 3861 IVc / 80b, a fibrous material body without the addition of solid particles has become known, which has densities of 16 to 144 kg / m ³ . The measures disclosed in this patent application, since they do not relate to the supply of solid particles, cannot be used either to improve the measures according to OE-PS 2 41 717.

Through the DT-AS 11 64 773 it has become known, glass fiber mats after the glass fibers with the Binder can be sprayed and collected on a conveyor belt, then added to the desired Pressing and hardening the mold. It has been shown that such pressing alone is not suitable desired great dimensional stability; u achieve. As will be shown later, however, the Use of this measure meaning.

The invention is based on the object of modifying the measures described in OE-PS 2 41717 so that that a product with high insulating properties and with the desired high dimensional stability is produced can be.

To solve this problem, the inventive method is characterized in that not from the deformable particles under the effect of their gravity a homogeneously and constantly flowing, den

Fiber stream ring-shaped surrounding particle stream is formed that the particles through uniformly radially Ring-shaped gas flows directed against the particle flow be thrown into the fiber stream, whereupon the volume of the deposit formed across the Mass of fibers is decreased. The inventive device for performing the inventive The method is characterized in that a ring-shaped surrounding the fiber stream for the particles Distributor and a nozzle system surrounding the fiber flow in a ring below the distributor Injection of the particles are arranged in the fiber stream.

Experiments have shown that this way of feeding the particles to the fiber stream makes it possible bring in a much larger amount of particles than with the measures according to OE-PS 2 41 717 is possible. This is mainly due to the fact that the amount of flowing particles and the gas flow are independent can be set to the desired value in each case. This is the case with the method according to OE-PS not possible. Rather, the method according to the OE-PS works with more nozzles, if one wants to introduce more solid particles into the glass fiber mat. But one always increases in the the same ratio is also used for the amount of the medium causing the atomization. This has been found to be disadvantageous in the described sense. It has also been shown to be advantageous that after the storage, the volume the deposit formed is reduced across the mass of fibers. This results in an intensified Defining the introduced particles within the fiber structure

It has been shown that the products produced with the measures according to the invention are such Quality that these products can be made in a number of different densities can, the presence of the solid particles is hardly visible. In particular, very dense panels can be used obtained with a high content of, for example, sand, which nevertheless have a very good appearance. Det Sand is completely enclosed in the mass of the product and does not have to be in the event of bumps the tendency to detach. The products manufactured with the measures according to the invention have a! »or great dimensional stability that cannot be achieved with any of the known measures. It is Nevertheless, the heat and sound insulation ability is given even with high sand content, because despite the solid Connection of the particles with the fibers, the particles with these in the meshing them only are in contact at points or along lines of short length.

Advantageous embodiments and developments of the method according to the invention are set out in the claims 2 to 4 and the device according to the invention described in claims 5 to 14.

In the drawing are shown examples of the dei serve to further explain the invention. The «following description refers to this« Examples. But it also includes a further de general presentation of the invention. The Figurei the drawing show the following

F i g. 1 shows a section of a plate made of mineral fibers, which in a known manner at de Reduction points with one another by means of a binder are connected, but without the addition of non-deformable particles,

Fig. 2 the same section, but after compression,

Fig. 3 shows a;) corresponding section as shown in Fig. 1, but not with the addition deformable particles according to the measurements according to the invention,

F i g. A is the same section as shown in FIG. but with a compression by the same force as shown in FIG. 2 is provided,

5 schematically shows a basic representation the device according to claim 5,

F i g. 5a shows the section Va from on a larger scale F i g. 5,

6 schematically, in perspective, approximately to scale the F i g. 5a shows a partial section of a somewhat different type of device according to the invention with the Features of claims 8, 11 and 12,

7 shows, on an even larger scale, a further development of the device part according to FIG. 6 with the additional features of claims 6, 7, 9 and 13.

8 is a plan view of the representation according to Fig. 7,

9 shows a partial view on an even larger scale, which shows the running of the particles on the distributor surface,

F i g. 10 to 12 in compared to FIG. 9 even bigger Scale partial views (partly in section) of a supply line (see FIG. 10) and of one perforated mask (see Figs. 11 and 12),

FIG. 13 on the middle scale, which lies between the scales of FIGS. 6 and 7, in perspective Representation a view of another embodiment with the features of claim 14, and

FIG. 14 on a somewhat larger scale than that of FIG. 7 is a partial vertical sectional view of FIG Embodiment according to FIG. 13.

In the F i g. 1 to 4 are A. B, C, D: A '. 3 '. C, D ': A ". B". C ". D": A '". B'", C ", D '" the crossing points of the fibers 2' and 12 'the embedded, non-deformable particles. 3 and 4 show the embedding, and the difference in compression at the same compressive force shows the increased dimensional stability as a result of the embedded particles 12 '. Such an increased dimensional stability cannot be achieved with the measures according to OE-PS 2 41 717. Otherwise one recognizes. that the particles 12 ', since they are only in contact with the fibers of the meshes enclosing them in points or along lines of short length, practically do not allow any thermal bridges to arise between the particles and the fibers, so that the desired high insulating capacity despite the particles introduced is maintained.

For the following see FIG. 5 and 5a. The fibers 2, for example glass fibers, are produced with a device 17 which, for example, has a body rotating at high speed, which has a circumferential jacket provided with holes through which thin material jets or streams are thrown out by the action of centrifugal force and drawn out into fibers will. The fibers are moved downwards as a fiber stream. The non-deformable particles 12 are located in an annular container 16. which is coaxial with the fiber stream. The exit quantity of the particles 12 is regulated by regulating elements 18. Below the container 16 is the one which surrounds the fiber stream in a ring shape

Manifold 35 'with the annular opening 19 from which the particles 12 flow out by gravity and then by blowing; one the fiber stream ring-shaped surrounding nozzle system 20 are subjected. By this blowing effect, the particles 12 are in blow in the fiber stream and its spatially uniform Causes distribution in the whole mass of the fibers.

Below the annular nozzle 20 is another annular nozzle 21 arranged through which the entire flow of the fiber-particle mixture passes. the Nozzle 21 can be driven to an oscillating movement (see claim 7).

A binder is supplied to this mixture through the spray guns 22. The mixture is then taken up by an endless conveyor belt 14 . Below the conveyor belt there is a suction device 14a, by means of which the volume of the shelf is reduced (see claim 3).

An oscillating movement of the nozzle 21 enables a particularly uniform distribution of the fibers the conveyor belt 14. A uniform mat is obtained in this way, which after the hardening of the binder results in a uniform plate.

In the embodiment according to FIGS. 6 to 12 the non-deformable particles to be introduced into the fiber stream 2, e.g. B. sand, in two funnels 30 out, from where they get into the pipelines 31. There is a transport screw in each of these pipes or screw 32 is provided, the diameter of which is smaller than the inner diameter of the pipeline. The two transport screws 32 are driven synchronously by a gear motor 43.

The pipes 31 have openings 33 (Fig. 10) which are arranged along a lower surface line and through which the screw 32 transported particles trickle. A channel 34 is arranged opposite each opening 33. The particles run along each channel and become in the form of thin rays surrounding the fiber stream in a ring shape Manifold 35 supplied, which has an inwardly inclined surface 36, the gradient of which is at least equal is the angle of repose of the particles on the surface.

The grooves 34 are arranged such that the points of impact 37 of the particles and the angle of inclination of the surface 36 of the distributor 35 are such that the particles trickling freely on this wall. Layers 38 form which spread out and merge along the lower edge 39 of the surface 36 to form a homogeneous and continuous layer. This layer is used for the action of the jet of air that emerges from the annular nozzles 40 provided at the base of the manifold 35. which has an annular blowing device 41. The blowing gas is introduced into the chamber of the blowing device through conduits 42 which are inclined in such a way that the particles are thrown into the rotating fiber stream in a direction which is the reverse of the rotation of the fiber stream.

The fiber stream with the particles evenly distributed in it then passes through a nozzle 44, the one oscillating movement is given about the axis 45. This nozzle allows an even distribution of the dei Fibers over a conveyor belt 14 serving for recording, on which a mat is formed. You Fibers are previously impregnated with a binding agent by means of atomizing guns 22. See also FIG. 5.

The F i g. 8 shows the arrangement of the grooves 34 of the same

The inclination is such that its slope allows the particles to run naturally (at least 30 ° in the case of sand) enables. Their direction is such that the points of impact 37 to form a continuous, homogeneous, constantly trickling layer, as described above ^, lead. These channels are on supports 46 mounted and arranged perpendicular to the distributor ring in order to reduce the space required by the device Limit minimum.

The arrangement of the transport screw 32 and its speed of rotation are such that one prepares a particle layer of substantially constant thickness over all the outlet openings 33 of the conduits 31. However, in order for each of each of these openings fed trough 34 appropriate quantities to get _5, shadow masks 47 provided, which are provided with holes 48 of different diameters. These masks are mounted over the gutters and can be rotated to feed the outlet openings 33 the hole appropriate to the amount one wishes to receive. A locking stop 49 is provided on each mask and works together with locking notches 50 in the line 31. This enables the mask to be set precisely for each selected hole.

To allow the removal of excess particles and clog the pipes too avoid, overflow outlets 51 are provided at the end 52 of the pipelines 31, which facilitate the removal allow these particles.

The amount of particles delivered by the manifold 35 depends on the diameter of the holes 48 the masks 47 and the speed of rotation of the transport screws 32.The latter is set so that that all holes meet their delivery, except for the overflow outlets 51, which are for dealing with a There are excess. The latter only give off particles in the event of the holes 33, 48 or the clogged incorrect handling and avoid breaking the transport screws 32.

In the variant shown in FIGS the particles guided into a funnel 53 are moved into an annular tube 54 by means of a transport device Conveyed in the form of a screw 55 without a core, which is rotated by a gear motor 56 receives. This line is arranged coaxially to the rotating body 17 or to the fiber stream 2 and is located above the inclined surface 36 of the annular manifold 35 in the manner as above is described. The line 54 has openings 57 through which the particles reach the inclined surface 36 run and at the same time on the lower edge 39 of the inclined surface of the manifold 35 a forming a continuous layer of constant thickness.

In addition 6 sheets of drawings

Claims (14)

Patent claims: 1. Process for the production of heat-insulating panels or shaped pieces from mineral fibers, in particular made of glass fibers, in which the mineral fibers immediately after their production as a fiber stream are moved downwards, while the downward movement of the fiber stream is not deformable Particles are supplied and a thermosetting binder is applied to the fibers and / or particles is sprayed on, the whole is laid down and the binding agent is hardened, characterized in that, that from the non-deformable particles under the effect of their gravity a homogeneously and constantly flowing fiber stream ring-shaped surrounding particle stream is formed that the particles through uniformly radially Gegvin the Teikhenstrom directed ring-shaped Gas streams are thrown into the fiber stream, whereupon the volume of the deposit formed transversely is reduced by the mass of the fibers. 2. The method according to claim 1, characterized in that annularly around the fiber stream a particle supply (38) is maintained by continuous replenishment and that the homogeneous and a constant flowing particle stream is formed by trickling down from this supply. 3. The method according to claim 1, characterized in that that the reduction of the volume of the shelf by i: inen suction across the mass of the fibers takes place. 4. The method according to any one of claims 1 to 3, characterized in that in the case of a strand-like bevel flow rotating about its flow axis the non-deformable particles with a direction opposite to the rotation of the fiber stream be thrown into the fiber stream. 5. Apparatus for the production of heat-insulating plates or shaped pieces from mineral fibers, in particular glass fibers, with a fiber production device for generating a downwardly moving fiber flow, with feed devices arranged below the fiber production device in the vicinity of the fiber flow generated for introducing non-deformable particles into the fiber flow, with an endless one Conveyor belt for receiving the fiber-particle mixture and with a suction device arranged below the conveyor belt for carrying out the method according to one of Claims 1 to <·, characterized in that a distributor (35 ', 35) and a nozzle system (20, 40, 41) surrounding the fiber stream in an annular manner for blowing the particles into the fiber stream are arranged below the distributor. 6. Apparatus according to claim 5, characterized by a nozzle system (40, 41) with fixed or movable nozzles. 7. Apparatus according to claim 5 or 6, characterized by one below the blowing device arranged, driven to oscillate movement annular nozzle (21, 44) for the passage of the total flow of the fiber-particle mixture. 8. Device according to one of claims 5 to 7, characterized in that the fiber stream annularly surrounding distributors (35) channels (34) for the supply of the particles in the form of thin jets its dei in relation to the direction of movement Fiber stream has inclined surface (3S), unc that the angle of inclination is at least equal to deiT Angle of repose of the particles on the surface is. 9. Apparatus according to claim 8, characterized in that the angle of inclination of the surface (36) of the annular distributor (35) and the meeting points (37) of the channels (34 trickling particles are matched to one another abge that on the surface of the distributing a uniformly thick, constantly trickling down particle layer in front of the nozzles (40) of the blower (41) is maintained. 10. Apparatus according to claim 9, characterized ge indicates that the channels (34), which are acted upon by a pipeline (31) through openings (33) lead to the annular manifold (35). 11. The device according to claim 10, characterized characterized in that the pipeline (31) consists of parallel tubes (31) in which transport screws or worms (32) are provided and which are provided with openings (33), the above the grooves (34) are arranged. 12. Apparatus according to claim 10 or 11, characterized in that each tube (31) to its end (52) has overflow outlets (51) for the particles. 13. Device according to one of claims 10 to 12, characterized in that each tube (31) with perforated masks (47) with holes (48) different Diameter is provided to regulate the cross sections of the Durchtnmöfinungen (33) for the Particle. 14. Device according to one of claims 5 to 7, characterized in that the feed member for the particles consists of an annular tube (54) above the inclined surface (36) of the annular Distributor (35) is arranged and the openings (57) and a transport device in Has the shape of a screw (55).