DE10316119B4 - Method and device for producing an extruded profile - Google Patents

Abstract

A process for producing an extruded profile from a mixture which is formed from small plant parts and binders, in which: - that mixture is passed and set through a preheating duct, a heating duct and a setting duct and - in which water is applied to the strand being formed; The water is supplied by the water entering the strand from inner walls, holes formed therein and / or heating angles / heating plates and / or a mandrel, characterized in that the water is introduced starting in the rigid area of the preheating duct and in the heating duct, in which the edge layer of the strand is heated to a temperature at which no more wear occurs, - whereby only enough water is introduced into the strand that no strand compression occurs and - wherein the water introduction continues to take place in such a way that after a last feed point a Temperature of the strand of up to 100 ° is reached.

Description

The invention relates to a method and an apparatus for producing an extruded profile.

State of the art

Out DE 200 18 347 U1 an extrusion press is known in which in a movable region of the pressing channel steam is applied to the strand. The strand is further heated in a further successive channel section.

task

The invention has for its object to provide a method and apparatus by which, or through which the strand can be cured at low energy consumption and a short length of the Abbindekanales.

solution

The above object is achieved by a method according to claim 1, and by a device according to claim 13.

The strand is brought according to the invention essentially by hot water, evaporating hot water or steam in the heating channel to its setting temperature.

If the heating of the heating channel has only one Temperierungsaufgabe, the invention teaches only to heat the heating channel so strong that the temperature corresponds at least approximately to the H2O inlet temperature. In this embodiment, the heating medium H2O passes preferably as saturated steam in the strand in order to condense in this initially with energy release.

If the heating channel serves as a superheater, it is brought to a significantly higher temperature than the steam inlet temperature. In this embodiment, the heating medium H2O passes preferably as superheated steam in the strand in order to condense in this initially with energy release.

If the heating channel serves as a steam boiler, it is heated to such an extent that the H2O, as it flows through it, evaporates and enters the strand as saturated steam or superheated steam, in which it initially condenses with the release of energy.

The invention dispenses with the production of a set outer layer of the strand and on a first reactor to produce a special smooth edge zone. The first reactor is still subject to wear, which is particularly caused by the sand content in the chips. This zone extends from the beginning of a significant compression in the filling and pressing chamber to the height in the press room, in which a thin edge layer of the strand is heated to a temperature such that the paraffin contained in the glue emerges and on the walls of the Abbindekanals one always regenerating protective layer against abrasion. Starting in the wear-free area of the Abbindekanals, so still in the rigid area of the preheating channel, at a distance, depending on the profile of the strand. from about 100 mm to about 900 mm before the front end position of the press ram or the front edge of the compression element, the invention teaches to enter the heating medium over a longer distance in the Abbindekanal. The length of the H2O entry path depends both on the extruded profile, the amount of H2O required, the gelling time of the binder and the performance of the press and in particular on the shape stability of the strand. In each case, the invention teaches introducing only so much H2O into the strand that it is not compressed during transport through the setting channel or heating channel, or that its shape is not adversely affected by transport, or that its density increases appreciably.

In practice, lengths of about 1 to about 10 m have been proven. As a guideline, a maximum length of up to about the amount of gelling time in min x of the capacity of the press in m / min plus a safety margin may be cited. With more dimensionally stable profiles, however, it has been found that less than about half of this distance is usually sufficient. The reason is that the spangle immediately after it has been softened by the H2O entry dries again and regains its original strength. The H2O enters the strand from a plurality of narrowest slits between the walls of the setting channel and the inserts described below. The slots are inventively kept so narrow that the smallest wear parts of the strand are larger than the width of the slots and therefore do not get into this. An inventive structure of the H2O supply is formed as follows:
The heating angles are provided with one H2O supply hole for each surface, or the heating plates with at least one H2O supply hole. The H2O feed hole is connected by bores with the grooves, which are introduced at a distance of about 50 mm to about 500 mm in the pressing direction in the strand-side surfaces. For square strands, the invention proposes a row of grooves in each of the four larger areas. From the corner surfaces generally no H2O discharge takes place. The groove contour preferably corresponds to that of feather keys according to DIN 6885. The groove depth at least the key height. As a particularly simple embodiment of Inserts, recommends modified feather keys according to DIN 6885 form E. Of these, a large part of the side surfaces are removed, so that when installing steam discharge slots of about 0.01 to about 0.2 mm wide on both sides. The steam outlet slots can wedge-shaped widening in depth. The lower surface of the key is also, preferably up to the area of the round ends removed by up to about 2 m. The insert is screwed into the groove. The advantage of this design is that narrowest steam slots can be realized in a simple manner, whose width is so small that even the smallest wear parts of the strand can not penetrate into the slots. Even if the slots become clogged over time, they can be easily cleaned by simply disassembling the inserts. For this purpose, the invention provides Abdrückgewinde in the feather keys.

For round strands or strand profiles with uneven outer contour teaches the invention to produce the groove with a ball cutter or erode in particularly complicated extruded profiles. The insert is formed in the outer contour such that there is a fixed seat in the groove and the described vapor exit gaps arise. The inner contour of the insert corresponds to the heating angle. The fixing is done by one or more screws or by soldering to the Heizplattenflächen not touch the strand. In a Schraubenbefestigung the invention proposes that the insert sits with a press fit in the groove or it builds into the insert a heat-resistant sealing cord.

The introduced in the entry section amount of steam is such that the strand is brought at the height of the last entry point to setting temperature.

If the desired setting temperature is below the evaporation temperature of the H2O, no overpressure occurs in the line. However, the invention provides that the steam or water leaving the strand can pass into a container via the withdrawal grooves and tubes described below and optionally condenses therein. This is at the same time a safety device in case of faults. If the press stops for a long time, the strand will heat up to more than 100 ° C, which will cause the steam to escape.

If a strand is to be produced with a particularly smooth, higher-density outer layer, the invention likewise dispenses with a reactor according to FIG EP 0 376 175 B1 or the follow-up developments. It merely arranges several grooves with inserts at short intervals of about 15 to about 45 mm at the beginning of the H2O entry. The number of closely spaced grooves may be up to about 12. This means that initially a larger H2O entry takes place. The edge zone of the strand is thus softened and densified and smoothed by the repressing parts of the inner zone.

After the area of the H2O entry, ie the actual heating channel, the strand passes into a setting tunnel of the same design, except for the unused H2O supply devices. The length of this section is such that the strand, after it has left it, is completely tied off. As length specification, the gelling time of the binder in min * of the capacity of the press in m / min can be called. However, this is a long shot.

For vacuum generation, the invention preferably uses an injection condenser, which it arranges at the heating angles. In simple terms, this is a larger tube, which is connected by lines with the withdrawal grooves. Approximately at the height at which the lines lead into the condenser tube, finely atomised cold water is injected, which causes the H2O to condense. The condensation can be initiated either by an auxiliary pump in motion, or by the fact that the extruder is first moved so slowly that the strand heats up to above evaporation temperature. The steam leaving the strand condenses in the condenser and permanently activates the condensation. The press is now brought to its working speed.

The condensate contained in the strand with exiting gases and Leimanteile which previously had to be exhausted consuming and less effective. In an embodiment of the invention, the condensate can be suitably cleaned on conventional systems from the foreign substances and fed as hot water to the steam or hot water generator. This results in a considerable energy saving.

In a similarly advantageous manner, the invention generates the vacuum by a vacuum pump, for example by a Roots pump.

The Abbindekanal can be kept shorter according to the invention, when the saw is placed at such a distance from the Heizkanalende that the strand can completely set by the heat contained in it. In this room, the strand can be covered by a simple, the strand umschleissende hood from which escaping gases are supplied to the described container.

The Abbindekanal and the Entdampfungskanal can be advantageously combined with each other, resulting in a smaller overall length.

Heating channels, in which square strands for pallet blocks are hardened, have so far consisted of fixed and movable heating angles. The individual heating angle are formed from plates screwed together, through the longitudinal bores heat transfer oil is performed. The construction of the heating angle from bolted angles is only seemingly simple. In fact, it requires a considerable effort to screw together two flat steels in non-commercial, so reworked width distortion-free and particularly straight, especially since the straightness must be maintained even at a working temperature of up to 220 ° C. In addition, a seal between the heating plates is required.

Surprisingly, the constructive solution of the invention to mill out the heating angles in one piece has proven to be simpler and less expensive. The reason lies in the high machining performance of today's milling machines and boring mills. Another advantage of the one-piece construction is that the grooves for the discharge of the H2O and the sealing elements can be inserted in the same setting. In addition, the location of the heat transfer oil wells can be determined without regard to screws. Therefore, the invention provides each strand-facing surface of a heating angle with two grooves whose openings point in the same direction. One groove is intended to receive the seal and the second removes the H2O. The groove for the seal protrudes from a leg and the groove for discharging the H2O from the inner surface of the, preferably, other leg. The withdrawal groove is arranged such that, when the two heating angles are in working division against each other, the two withdrawal grooves are within the sealing grooves. Square pallet blocks usually have bevelled corners. For blocks of dimensions 100 × 145 and 145 × 145 mm, they are bevelled by 15 × 15 mm. A preferred position of the withdrawal groove is in the region of this chamfer. It is not necessary to make the inner corner of the heating angle beveled, but rather it can be made sharp-edged. Although it is in principle possible to dispense with such extruded profiles on the Abzugsnuten and quasi use the free corner as Abzugsnut, but there is the possibility of condensation, with condensation can damage the strand. The invention therefore prefers the withdrawal grooves, through which the H2O is derived. It also teaches under each lower corner of the strand and possibly also above each upper corner of the strand to introduce a vent groove in the heating angle.

The withdrawal grooves are connected by lines to the condenser.

The sealing grooves protrude in the longitudinal direction either through the entire leg or are guided directly to the ends of the angle to leg inner side. In the sealing grooves, the invention provides an extruded profile made of heat-resistant plastic, z. Viton, PTFE or PEER. The protruding from the sealing groove side of the sealing profile is extruded with a kind of teeth, resulting in multiple sealing lips and allows the heating angle in their distance from each other can be moved slightly. The hardness of the sealing profiles can be about 50 to 90 Shore. Such sealing profiles are not commercially available. But they are from some manufacturers, eg. B. extruded from hydraulic seals according to the customer information. Equally advantageously, the invention forms the sealing profiles similar to one or two-sided Nutringen from the field of hydraulic seals.

The heating angles are generally made in a length of 2 to 4 m, preferably 3 m in length. The movable heating angles are kept shorter by 2 to about 10 mm so that they can be opened. For vacuum generation, this means that foreign air enters the system through the resulting gaps and reduces the formation of vacuum. However, this is not disadvantageous to the invention, which works primarily in pressure ranges of about 0.2 to 0.8 ata, preferably 0.5 ata. Theoretically, with condensation, a pressure of up to about 0.07 ata can be achieved. This would, however, cool the strand too much. The supply of external air has therefore not affected in practice as a disadvantage.

In a further advantageous embodiment, the invention seals off the gaps between the movable heating angles by means of hinged sealing straps. These sealing bars are provided with the known seals and allow the individual movable heating angle to move to the necessary extent to each other radially to the pressing direction while maintaining the tightness.

In a further equally advantageous embodiment, the invention provides the movable heating angle or heating plates frontally with sealing profiles or sealing plates and seals them against each other. In order to open the heating angle together, the movable heating angle are connected to each other, z. B. screwed and when opening together in the pressing direction by means of a force transducer, z. B. a hydraulic cylinder moved by a few mm in the pressing direction. The unfolding of the movable heating angle is conveniently done by hydraulic cylinders, with gas pressure or Gaszugfedern the weight of the movable Heater duct debris largely compensate, which acts on the lying in the pivot axis of the movable Heizenchtrümmer wave, which guarantees a uniform opening, only a small torsional force.

In the previous heating channels fastening in the pressing direction is carried out by a pull rod, which is provided at both ends with hinge eyes. If the movable heating angle can be opened independently of each other and the sealing done by seals on the front side, the invention teaches to use instead of the tie rods cylinder. Thus, the movable Heizkanalwinkel can be shifted to one another to the necessary extent.

Existing extruders can also be modernized advantageously with the invention. The heating angle of the heating channels are provided in the manner described above with the grooves. Only the withdrawal grooves may need to be kept flatter. The length of the existing heating channels is about 30 to 33 m. They can be shortened with the invention to vorgenante length.

Round strands are currently made in a split in two halves heating tube. The invention, however, teaches to work out the strand contour of two opposing plates. This can be done by deep hole drilling. Here, the two plates are annealed, preprocessed and screwed together or welded and then the longitudinal bore for the extruded profile and the heating bores are introduced. In the lower heating plate then the Abzugsnuten be incorporated and in the upper the grooves for the sealing profiles. Of course, instead of deep drilling, the strand contour can also be produced by milling, which the invention provides, in particular for round profiles with a two-edge flattening. The extraction grooves end 2 to 5 cm in front of the heating plate ends. The sealing grooves in the upper heating plate are outside of the withdrawal grooves and are made at the plate ends in the arc to the extruded profile. This ensures a sufficient seal in a simple manner. In spite of the external air flowing in between the upper heating plates, the invention generally achieves a sufficient vacuum. If this is not sufficient, especially in the modernization of existing extruders, the invention sees an additional vacuum pump, z. B. a Roots pump or she uses the above-described seals.

The heating angle or heating plates are connected by hinged together and radially against each other. They are pressed together by force transmitters with a defined pressure and determine the density of the strand. In processes in which the strand density is determined by the mandrel, the heating plates press against the strand only with such a force that the heat input can occur without large gap losses or they determine the strand density by a defined pressure during the strand transport. In case of faults or emptying, the heating angle or heating plates must be opened. In older presses this happens due to the sheer muscular strength of several people. In newer this force is reduced by counterweights. The latter cost about the same as hydraulic folding devices, but require considerable space in the width. The invention, however, uses the simplest cheapest and narrow-build solution Zuggasfedern or gas springs. These are preferably provided with a force that just overcomes the weight heating angle or hot plates and thus prevents accidental collapse.

It has been recognized that dry reuse is particularly suitable in a pressure range of about 2.5 to about 9 ata, and in exceptional cases higher. Superheated steam has only slightly higher usable enthalpy. For strands of 95 mm diameter, for example, dry saturated steam of 4 ata has proven to be particularly favorable when the strand is heated to approximately 100 ° C. and a vacuum of 0.5 to 0.6 ata is applied in the devolatilizing channel. It has been shown in experimental measurements that the enthalpy utilization of the H2O succeeds very well and the strand temperature is advantageously reduced without any disadvantageous prolongation of the setting time. The length of the Abbindekanal in this example was only about 1/3 of the product of the gelling time of the binder in min * the power of the press in m / min.

In order to reduce the energy requirement and thus the production costs through the use of humid small parts of up to 8% or more, the invention improves the energy balance by improving the energy balance DE 199 62 513 A further developed. This teaching is characterized in that the mixture is composed in such a way that it does not cure at all or only insignificantly, and that an agent which causes or accelerates a batch hardening is added to the mixture only in the region of the extrusion device. The invention makes use of this teaching by adding liquid or powder to the small parts in front of the extruder, and the hardener first through the mandrel and / or through the slots of the first, up to about 12 at a closer distance of about 15 mm to about 45 mm successive inserts. It improves the technique DE 199 62 513 A1 but completely by doing so crucial that she processes the small parts with the glue at a higher temperature than usual. It also solves a different task than this technique DE 199 62 513 A1 underlying. Essentially, the task is to prevent the batch from setting before it is processed in the extruder. However, the invention does not have the task to extend the possible residence time of the batch, but use the energy contained in the small parts after the dryer for curing. So it does not cool down the small parts as usual so that their temperature after the glue mixer is below about 50 ° C and the mixture can be processed for a few minutes, but it leaves it in a higher temperature range, in which they without or set with only a small amount of heat. The temperature is kept as high as possible. It may be 60 ° C. to about 90 ° C. for liquid glue, ie up to the temperature at which the glue does not dry out until it has been compacted in the extruder. With powdered glue, the temperature can be significantly higher. However, the steam exiting the chips must be removed to avoid condensation on the walls of the device. In the temperature range of up to approximately 100 ° C., the use of pulverulent glue is particularly advantageous, since the glue powder adheres well to the slightly wetter surface of the small parts.

The required energy to heat 1 kg of chips with a moisture content of 10% at 0 ° C is about 1.65 kJ. If, as the earlier chip entry temperature, 45.degree. C. and the chip entry temperature into the press 90.degree. C. according to the invention, there is a saving of 74.25 kJ per kg of chips during setting, since this amount of heat no longer has to be fed to the strand ,

The heating channel can be kept considerably shorter than with the use of small parts with normal temperature, usually a length of about 1/3 of the product from the setting time is sufficient (gel time of the binder in min * the performance of the press in m / min, as only one After leaving the heating channel, the strand is sufficiently stable that it only has to be evaporated between guide rails.The guide rails are compressed either with clamping elements as in the heating channel or only by springs. In most cases, the latter is sufficient and the springs have only the task of possibly preventing a lengthwise extension of the strand The total devolatilizing channel can have a length of up to approximately that of the product from the setting time (gelling time of the binding agent in minutes of the performance of the press in m / min. Usually, however, 1/3 is sufficient gt in a provided with a lid pan. It is sealed against the unpressurized escape of steam. The leaked from the strand H2O is passed from the tub via lines in the container already described.

Auführungsbeispiel

The invention will now be described by way of example without limitation of the general inventive idea using exemplary embodiments with reference to the drawings, wherein the rest of the disclosure with respect to the disclosure of all unspecified in the text details of the invention is expressly noted. Show it:

1 a section through an extruder.

2 a section on the line II according to 1 ,

3 a detail view in the direction of arrow II according to 2 ,

4 a section on the line III-III according to 3 ,

5 a section on the line III-III according to 3 ,

6 a detail section through a heating angle.

7 a section on the line II according to 1 ,

8th a section on the line II according to 1 ,

9 a plan view of a heating plate.

10 a section on the line IV-IV according to 1 ,

11 a section through a seal.

12 a section through a Entdampfungskanal.

13 a section through a Abbindekanal.

14 a detail section through a movable heating angle.

15 a detail section through a built-in seal.

16 a detail section through a built-in seal.

17 a section through a Abbindekanal.

18 a section through a Abbindekanal.

1 , shows a section through an extrusion press. As a press 1 serves in the embodiment, a continuous press according to the EP 1238 792 A2 , However, it can be any other press, z. B. a ram extruder can be used. Shown is the extrusion, so the pressing without a hole. Of course, mandrels of any design can be used.

To the press 1 closes the known rigid preheat channel 2 at. On this follows the heating channel 3 , the tie channel 4 and the devolatilizing channel 5 ,

In the exemplary embodiment, the heating channel consists of the partially movable section 6 with radially teilbeweglichen walls 7 and the section 8th with radially movable walls 9 , The section 7 is only required for very sensitive extruded profiles, even after leaving the preheating channel 2 still need a certain radial clamping in order to be able to be transported. For more stable strands, the entire heating channel 3 designed with radially movable walls. In the embodiment, the partially movable wall 7 through the stop 10 prevented, at the preheat channel end 11 to move radially. The distance from the leading edge of the compression element or the ram in dimension 12 is dimensioned such that in the area of the first H2O outlet opening 13 no wear on the inner walls 10 of the preheating channel 2 more occurs. The measure 12 is approximately between about 100 to about 900 mm. If the strand is to be provided with a higher density, particularly smooth outer layer, the H2O outlet openings will be at the beginning of the H2O detection zone 15 at a closer distance from each other from about 15 to about 45 mm in size 16 held. The number of closely spaced H2O outlet openings can be up to about 12. The following H2O outlet openings may have a distance of about 50 mm to about 500 mm to each other. It is introduced by the H2O outlet openings so much of H2O or energy in the strand that in the height of the last H2O outlet opening 17 the strand is completely brought to setting temperature.

If the setting temperature of the strand is below 100 ° C., no overpressure is produced. The leaking H2O is in this case depressurized in the container 24 directed.

After the heating channel follows the Abbindekanal 4 in which the binder of the strand binds or gels. The Abbindekanal is kept pressure-free. For this purpose, the invention sets the line 25 to the container 24 , In this, the H2O, if necessary, condense and is subsequently cleaned and returned to the heating circuit. Should the heating channel 3 heating the H2O to working temperature is the boiler 26 dispensable. It is then just a pump in the line 27 required. If the heating channel is to overheat the H2O, the temperature in the boiler will increase 26 kept smaller than in the heating channel 3 , Next, the heating energy essentially through the boiler 24 be generated. The heating channel 3 has the quasi a tempering function.

After the Abbindekanal follows the Entdampfungskanal 5 , If the line temperature is below 100 ° C, the vacuum pump will operate 29 or a condenser in the train generates a negative pressure which is dimensioned such that the evaporation temperature of the H2O is below the line temperature. The condenser is preferably designed as an injection condenser.

The binding channel 4 and the devolatilizing channel 5 can also be combined with each other, which means that their functions overlap, allowing for a shorter overall length.

2 , shows a section through a heating channel on the line II according to 1 , The example is with sharp corners 30 is dropped. In general, with strands for pallet blocks, it is not necessary to match the corners to the contour of the strand after the preheat channel. Escaping gases or vapors can pass through the degassing grooves 31 and the pipes 32 be dissipated. An escape into the environment is through the seals 33 prevents getting into the grooves 34 are used. The heating channel is heated in the embodiment by hot water or heat transfer oil, which through the holes 35 flows. If the heating medium has the task of merely tempering the heating channel, the temperature is adjusted approximately to the inflowing H2O. If it has the task to overheat the steam, a higher temperature than the incoming steam is selected. However, the heating channel can also work as a "boiler". In this case, so much heat transfer oil is supplied at a suitable temperature that through the holes 36 Guided water evaporates in these and passes as saturated steam or superheated steam in the strand. In the 1 said vapor exit points are grooves 37 in the inserts 38 are admitted. The H2O succeeded from the hole 36 over the tap holes 33 into the distribution groove 40 and from these through the slots on the sides of the inserts 38 in the strand. As a suitable height of the distributor groove in the measure 41 can be called up to about 2 mm.

The seals 33 made of a heat-resistant plastic with their geometry described later allow a radial dodge the movable heating angle 42 while maintaining the tightness of the interior 43 ,

3 shows a detail view in the direction of arrow II according to 1 , In the groove 44 is the insert 45 inserted. In the exemplary embodiment, it consists of a key according to or similar to DIN 6885 form E which is refinished on the side surfaces such that the slots 46 in a width of about 0.01 mm to about 0.2 mm in dimension 47 arise. The post-processing can be done in the simplest way by grinding. According to the invention, the slot width is in dimension 47 smaller than the debris of the strand and these can not get into the slots and can clog them. Of course, it is also possible the slots without rework of the insert by a suitable choice of fit between the insert 45 and the groove 44 to create. The inserts are in the embodiment by the screws 48 attached and can through the thread 49 slightly out of the groove 44 be pressed. Of course, the invention also contemplates other forms of inserts than appropriate.

4 shows a detail section on the line III-III according to 3 , The heated H2O passes through the hole 50 into the tap hole 51 and into the distribution groove 52 the slots 53 in the strand.

5 , shows a detail section on the line III-III according to 3 , The side walls 54 of the insert 55 are reworked obliquely in the embodiment, resulting in a higher vapor flow rate.

6 shows a detail section through a Vorheizkanal or a heating channel with adapted to the strand corners 56 , In the preheat channel are the corners 56 customary adapted to the strand contour. In the case of the heating channel, this can be an advantage for a better surface of the strand, but is generally not carried out. The invention sees in the preheating channel, if necessary, a H2O discharge from the corners 56 in front. For the H2O supply is the bore 57 brought in. The H2O passes over the blind hole 58 in the strand. The exit column 59 with a size of about 0.01 to about 0.2 mm in size 60 be through the insert 61 formed, which at its base 62 profiled to the H2O Duchlass. It is for example by the screw 63 attached. put, rounded or stranded 58 be executed accordingly.

7 shows a section on the line IV-IV gem. 1 for round strands. The hole 64 can be cut out both by a solid hot plate 65 and the movable heating plate 66 be generated, as well as by deep hole drilling. In the latter case, the heating plates 65 and 66 preprocessed and stapled and then deep drilled. When finishing should be in measure 67 a gap of about 0.2 mm to 5 mm remain when the movable heating plate 66 pressed against the strand. The diameter in the measure 68 is about 0.2 to 2 mm larger than the diameter of the strand. With increasing wear of the wear parts of the extruder also increases the diameter of the strand. So that the strand is not between the heating plates 65 and 66 clamps, the invention sees a tangential chamfering 69 in front. She can be at an angle 70 about 5 [deg.] to 15 [deg.]. The seals can both in the movable heating plate 66 (as shown), as well as in the rigid heating plate 65 be admitted. The withdrawal grooves preferably place the invention in the rigid (or lower) heating plate. The heating is done by heat transfer oil or hot water through the holes 71 ,

8th shows a section on the line IV-IV gem. 1 for a flattened strand. The strand contour 72 is by milling out of the rigid hot plate 73 and the movable heating plate 74 generated. The further construction is carried out according to 6 , To clamp the strand between the heating plates 73 and 74 To avoid, it is advantageous the curves at an angle in the measure 75 from about 5 [deg.] to about 15 [deg.] with a straight line 76 extend tangentially. To save weight and to facilitate the opening of the heating channels, the corners can 77 be removed.

9 shows a plan view of a heating plate for round strands. The withdrawal grooves 78 become dimensioned to such a distance 79 to the heating plate ends 80 held that the fitting gasket 81 (drawn in phantom) can lie in the support surface and seals the strand to the outside. The deduction is made through the holes 82 , The seals 83 are led to the strand. A most extensive seal is due to the abrasion of the protruding parts of the seals 81 reached by strand.

10 shows a cross section through heating angle for square extrusions. The rigid heating angle 82 and the movable heating angle 83 are in cross-section in about the same design worked out in one piece. Contrary to the first impression, working out the contour from a annealed steel block is considerably cheaper than screwing two legs together, as in 3 , In both heating angle is the groove 84 for the seals 85 incorporated. In the rigid heating angle 82 are the two trigger grooves 86 milled, which protrude to just at the end of the angle. The invention dispenses with angular strands with chamfered edges then on the flue grooves if no condensation occurs and the chamfer 87 sufficiently large, z. B. 15 x 15 mm. The H2O and the extraneous substances emerging from the strand are easiest via lines that are in the screw joints 88 ends, fed to the capacitor. The necessary heat energy is the heating angles through heat transfer oil or hot water, through the holes 89 fed in the usual way. The corners 90 The heating angle can instead of sharp-edged, as shown, rounded or the strand 91 be executed accordingly.

11 shows a cross section through a sealing profile 92 , It is in the assembled state under the number 52 in 7 , shown. Its width and height depend on the heating angles.

As a guide for the width in the measure 93 can be 3 to about 15 mm and in height for height 94 from 4 to 20 mm. The upper surface is toothed, with the teeth an angle in dimension 95 from about 15 deg. to about 90 deg. at a depth in gauge 96 may have up to about 4 mm. A preferred embodiment has a height in dimension 94 of about 15 mm, a width in the measure 93 of 9 mm, a tooth angle in the measure 95 of 35 [deg.] and a tooth height in the measure 96 of 2.5 mm. The sealing profile 32 is extruded and cut to the needs. It is made of heat-resistant plastic z. As PEEK (polyether ether ketone, Virtex <(R)>) or FPM (fluororubber, Viton <(R)>) or manufactured. A suitable hardness can be called 55 to 90 Shore. Of course, other advantageous shapes and designs for the seal can be selected.

12 shows a cross section through a Entdampfungskanal. The illustration is schematic. The movable heating angle 97 is on the folding bracket 98 attached radially displaceable and is by the force transmitter 99 in a known manner against the rigid heating angle 100 pressed. The heating channel is made by screws 101 secured and can around the axis 102 be opened. For this purpose, no or only a small amount of force is needed, the invention is similar to the weight of the swiveling debris by Gaszugfedern 103 out. The gas tension springs are an extremely inexpensive and space-saving alternative to counterweights or hydraulic solutions. The off the strand 104 escaping gases and the H2O get over the lines 105 in the injection condenser 106 , In the condensation room 107 is, preferably at the level of the lines 105 , from the tube 108 very atomized, cold water 109 injected, which condenses the H2O. In the case that too much external air is supplied, or too much inert gas is contained, the vacuum is increased by an additional pump. The condensation is initiated either by this auxiliary pump or an auxiliary pump, or by the fact that the press is first started slowly, whereby the strand is heated to above 100 ° C and H2O emerges as vapor, which condenses in the condenser and the Partial vacuum generated. Subsequently, the performance of the press is increased. The vacuum may be between about 0.2 to about 0.8 ata, preferably about 0.5 ata. This means that the system tolerates a certain amount of external air or inert gas. The strand is exposed to the partial vacuum only in the necessary length. This means that the vacuum device does not have to extend over the entire Entdampfungslänge the heating channel. Instead of the gas tension spring 103 It is also possible to use a gas spring which presses in the opposite direction.

Instead of the injection condenser, any type of condensation or a vacuum pump can be used just as advantageously.

13 , shows a section through a heating channel. Instead of the gas tension spring of 12 used in the same advantageous manner in the embodiment, a gas spring 110 , If the strand is heated above 100 ° C., an overpressure forms in the interior in the region in which no H2O condenses. To limit the overpressure and pushing apart the heating angle 111 To prevent, especially at a standstill, the strand heats under increasing pressure, the invention sees the pressure relief valve 112 in front. It is not necessary for strand temperatures below 100 ° C. In this case, the leaking gases; Vapors or water directly into the container 113 directed. Here they can condense, be cleaned and returned to the heating circuit with the addition of fresh water.

14 , shows a detail section through the movable heating angle. The embodiment deals with a version of the invention, in which all movable heating angle 114 ; 115 from the preheating channel 116 together around the measure 117 be moved. The individual heating angles are with seals 118 made of heat-resistant plastic and at the ends with screws 119 connected. In the working state of the device, the heating angle through the cylinder 120 against the preheat channel 116 pushed. The folding bracket 121 is connected to the rigid heating angles and does not move.

If the movable heating angle to be opened individually, the invention provides for each heating angle a separate cylinder.

In contrast to the pamphlets DE 102 45 285 A1 and DE 102 45 284 A1 For example, the cylinders do not use double-acting cylinders to control the compression, but advantageously two single-acting plunger cylinders 122 and 123 , This results in a much simpler structure, since the cylinder no connection to the heating angle 114 need. A double-acting cylinder must have a gimbal on the cylinder tube and a hinge eye on the rod for the movements of the heating angle 114 to be able to compensate.

15 shows a detail section through the area of the sealing of the heating angle. The sealing profile 124 is shown in a relaxed state and with two sealing lips 125 , similar to Nutringen in the hydraulic sector, provided. There are also versions with only one sealing lip, or with multiple sealing lips possible. The sealing profile 124 is out is is extruded and cut to the needs. It is made of heat-resistant plastic z. As PEEK (polyether ether ketone, Virtex <(R)>) or FPM (fluororubber, Viton <(R)>) or manufactured. A suitable hardness can be called 55 to 90 Shore. The offset in the measure 126 is such that the heating angle can go completely or almost together.

16 shows a detail section through the area of the sealing of the heating angle. The sealing profile 122 is shown in the relaxed state and with two oppositely acting sealing lips 128 and 129 , similar to Nutringen in the hydraulic sector, provided. There are also versions with multiple sealing lips possible. The sealing profile 127 is out is is extruded and cut to the needs. It is made of heat-resistant plastic z. As PEEK (polyether ether ketone, Virtex <(R)>) or FPM (fluororubber, Viton <(R)>) or manufactured. A suitable hardness can be called 55 to 90 Shore. The offset in the measure 130 is such that the heating angle can go completely or almost together.

17 shows a schematic section through a Abbindekanal 131 and deals with the sealing of the spike hole 132 , The thorn 133 is with an electric heating cartridge 134 executed, which is at a known height in the strand. The Abbindekanal consists of the section 135 , the preheating channel and the heating channel, the section 136 , the binding channel, the degassing section 137 and the intermediate area 138 between the binding channel and the saw. The line 139 shows the position of the rear saw blade of the saw, which intercepts the strand or saws, for example, to pallet blocks. The intermediate area 138 is by a longitudinally variable sealing element 140 , z. B. sealed a bellows. the spike will go after the heating cartridge 134 in the measure 141 made smaller by about 0.2 to about 1.5 mm, so there is no additional friction. In the area of the devolatilization section and possibly a little bit beyond, the mandrel becomes dimensioned 142 further reduced. The measure 142 is chosen so that the desired vacuum is generated despite the gap and the pressure in the degassing section is lower than in the saw housing.

Thus, according to the invention sawdust through the spike hole 132 sucked and clog this. This measure eliminates the somewhat problematic Dichtstopsel. The "Ersatzdichtstopsel from sawdust 143 wanders with the skein in the saw, but is constantly renewed.

18 shows a schematic section through a Abbindekanal 144 and deals with the sealing of the spike hole 145 , The construction of the binding channel 144 corresponds to 17 , through the thorn 146 However, hot water, evaporating hot water or steam over the cross holes 147 introduced into the strand. The strand is thus from the Dornloch 144 wholly or partially brought to setting temperature. Instead of the illustrated transverse bores 147 From about 1.5 mm to about 5 mm in diameter narrowest slits are preferably sawn or eroded in a width of about 0.1 to about 1.5 m in the mandrel, whereby there is no risk of clogging by the smallest wear parts of the strand. The arrangement of the transverse bores or slots preferably takes place helically around the mandrel 146 , The back Dorntrumm 148 is in measure 149 as long as possible, but only in such a length that the strand is not compressed during withdrawal. The leading edge 150 of the thorn 146 can (also at 17 ) over the end 151 of the binding channel 143 until almost to the back of the saw range.

Claims (14)

A method for producing an extruded profile from a batch formed from small vegetable parts and binders, comprising: - that mixture being passed through a preheating channel, a heating channel, and a setting channel and setting and - wherein water is applied to the forming strand; - wherein the water supply takes place by the water from inner walls, holes formed therein and / or heating / heating plates and / or a mandrel enters the strand, characterized in that - the water is introduced starting in the rigid region of the preheating and in the heating channel, in which the edge layer of the strand is heated to a temperature at which no more wear occurs, - where only so much water is introduced into the strand that no strand compression occurs and - wherein the introduction of water continues to be coordinated so that after a last feed point a Temperature of the strand of up to 100 ° is reached. A method according to claim 1, characterized in that the water entry into the strand, in Pressing direction, starts at a distance of about 100 to about 900 mm in front of the leading edge of a compression element or the front end position of a ram. A method according to claim 1, characterized in that the penetration of foreign air is prevented in the strand by sealing bow. A method according to claim 1, characterized in that the escape of water from the Abbindekanal is prevented by sealing strap. A method according to claim 1, characterized in that the ingress of foreign air and the escape of gases in / from the / m strand by seals between the end faces of the movable heating / heating plates is prevented by the movable heating / heating plates in the working position in the pressing direction against each other be pressed. A method according to claim 1, characterized in that the water is introduced as a re-steam or superheated steam in a pressure range of about 2.5 to about 9 bar or higher, preferably at 4 bar in the strand. A method according to claim 1, characterized in that hot water, evaporating hot water or steam from narrowest slits or transverse holes in the mandrel, in the region of a preheating channel ( 2 ) and / or the following channels are placed in the strand. A method according to claim 1, characterized in that the water condenses with energy release in the strand. Method according to one of the preceding claims 1 to 8, characterized in that the from the heating channel ( 3 ) and / or the Abbindekanal ( 4 ) and / or a degassing channel ( 5 ) leaking gases and water are discharged into a container. Method according to one of the preceding claims, characterized in that the voltage applied to the strand parts of the Abbindekanals are tempered so that they have about the same temperature as the water supplied and the heat energy is fed to the strand heating the water outside the Abbindekanals. A method according to claim 1, characterized in that the voltage applied to the strand parts of the Abbindekanals are heated to a higher temperature than the supplied water and the heat energy is supplied to the strand heating the water from the flowed through by him heating / heating plates Abbindekanals. A method according to claim 1, characterized in that the adjoining parts of the Abbindekanals are heated and have a higher temperature than the supplied steam, the heat energy is supplied to the strand heating substantially the water outside the Abbindekanals and the water in the heating / heating plates overheated becomes. Apparatus for carrying out the method according to one of claims 1 to 12, comprising: - a press ( 1 ), with a press die or with a compression element - a preheat channel ( 2 ), which is addressed to the press ( 1 ), - a heating channel ( 3 ) placed on the preheat channel ( 2 ) and a binding channel ( 4 ), characterized in that - starting in the rigid region of the preheating channel ( 2 ) are formed at a distance of about 100 mm to about 900 mm to the front end position of the press ram or the front edge of the compression element to strand strand facing water outlet openings, and - the device is designed such that through the water outlet openings as much water as heating medium in the strand is introduced, that in the height of the last water outlet opening of the strand is completely brought to setting temperature. Apparatus according to claim 13, characterized in that it comprises a mandrel, and that hot water or steam is introduced through the mandrel in the strand.

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