DE3625358A1 - Process for processing of viscous compositions, for example hot-melt adhesives - Google Patents

Abstract

In a process for melting hot-melt adhesives, blocks (40) of the adhesive are completely enclosed in a film envelope and melted together with the film envelope in a pressure melting device (10). In a cylinder (12) of the pressure melting device, the material is pressed with the aid of a piston (20) against a heatable plate (16) provided with discharge channels (34, 14), so that the film and the adhesive melt on the plate (16) and emerge through an outlet (38). In the process, the film envelope prevents adhesion of the adhesive to the walls of a feed shaft (26) and to the interior walls of the cylinder (12). <IMAGE>

Description

The invention relates to a method for melting thermoplastic or thermosetting compositions according to Preamble of claim 1 and a device to carry out this procedure.

In particular, the invention is concerned with processing processing of highly viscous adhesive masses, such as wise hot melt adhesives.

When processing hotmelt PSAs or ver comparable enamel masses result from the upper surface stickiness of the material problems during transport and when storing and feeding the material a melter.

In one known method, the hot melt pressure sensitive adhesive substances are first poured into blocks after formulation, those for transport and storage individually in siliconized cardboard boxes are packed. Who before processing the blocks in open melting vessels or agitators melted. Since the material melts over meh is kept at a high temperature for several hours there is an impairment of the adhesive properties by thermal oxidation and by thermal aging the adhesive additives. In addition, there are high costs for the packaging material and its disposal.

It is also known to be the hot melt pressure sensitive adhesive in barrels to fill and to open in barrel melters with exclusion of air melt. In this case the thermal load less when melting, since the contents of the barrel are not total melted together, but only melted on the front becomes. However, there is a greater thermal load  when filling the adhesive into the barrels opposite, because the glue is due to its poor heat conductivity and the relatively large barrel volume cools down very slowly. Another disadvantage is in that the investment costs for barrel melting plants ver are relatively high. The melting of the material in the barrel melting system is relatively slow, and at a barrel change requires a downtime of about 20 mi grooves are accepted. To provide larger Amounts of liquid adhesive are therefore considerable equipment required.

To avoid these disadvantages is in DE-PS 31 38 222 and in DE-OS 32 34 065 a method been hit, in which the hot melt pressure sensitive adhesive in egg a mixing extruder in the form of a thin strand with a Diameter of about 5 cm extruded and with an as Release agent-serving tubular film, in particular Polyolefin film is wrapped. The further processing takes place in a melt extruder in which the film melted and dissolved in the adhesive. The melting required to carry out this process however, extruders are very expensive.

For melting granulated hot melt adhesives Pressure melting devices are known in which the Granular and therefore free-flowing output material on the side of a cylinder funnel into the interior of the cylinder and with Using a piston against a cylinder bottom heated plate is pressed. By touching with the hot plate melted adhesive is immediately bar through outlet channels formed in the plate to a Discharge. This comparatively simply given up Built-in device allows even larger glue quantities in the shortest possible time and with low thermal loading  melt the load of the adhesive.

So far, such pressure melting devices could ever but not for melting highly viscous, not granular that can be granulated or only granulated with special additives Masses are used. Because of their surface adhesive these masses adhere to the pressure Inner surfaces of the cylinder of the pressure melting device, so that the piston sticks.

The invention has for its object a cost-effective stating procedure that allows gluing high viscous masses in a simple and cost cheap device with low thermal load melt down. Furthermore, an advantageous Vorrich tion to perform this procedure.

These tasks are solved by a procedure with the features specified in claim 1 and by a Device according to claim 6.

According to the blocks of the melted Material completely wrapped, for example in a film enclosed, and in the wrapping of a pressure melt device supplied as for melting granules is known. When feeding the material to the enamel device prevents the adhesive from sticking material on the walls of the feed shaft. About that it has also been shown that the wrapping is also an adhesive material on the inner surfaces of the cylinder Pressure melting device and thus blocking the Kol bens prevents, although the wrapping when printing exercise is destroyed. Apparently, the wrapper remains on the side of the block facing the piston at least so far intact that there is an entry of the material into the joint between the piston and the cylinder wall to the end  the piston stroke reliably prevented.

The pressure melting device has a relative simple construction on, so that the investment costs essential are lower than when using extruders or Barrel melting systems with comparable performance. The pressure melting device allows easy adjustment of the Material throughput to the respective need, for example by varying the piston force without problems occur in temperature control. A continuous one Flow of the molten material, such as when applying pressure sensitive adhesive by spraying If necessary, it can be connected downstream Buffer systems such as gear pumps or the like achieved will.

Because the blocks of the material to be melted completely included in the wrapper can be on one agile packaging during storage and transportation of the material can be dispensed with. The blocks can immediately telbar in the production in a forming the envelope Foil are filled so that labor-intensive packing gears are eliminated.

The bottom plate with pressure channels melting device through which the material is pressed , can be designed so that the film is in print mechanically tears open. In this case, he can Processes according to the invention also for processing high viscous compounds such as joint sealant or the like be used at room temperature, especially since the after Squeeze the sealant out of the cylinder residual film can be removed if necessary.

The method according to the invention is particularly advantageous However, when processing thermally meltable  materials such as hot melt pressure sensitive adhesives. When processing The processing of such materials is melted down zen, so that disposal of the film residues is not required is.

The material only melts when it is touched directly heated floor plate. The pressure exerted by the piston on the one hand causes an intensive touch of the material with the bottom plate and thus an acceleration of the Melting process and on the other hand an immediate Ab transport of the molten material through the outlet channels of the base plate. This makes a high material throughput and extremely low thermal Material load reached. Because the melting process practically with the exclusion of air, on the one hand thermo-oxidative degradation of the molten material and on the other hand, an unpleasant smell in the vicinity of the Avoided melting device. In addition, a achieved considerable energy savings since only those ever because the required amount of material is melted and heat losses due to the close contact of the material with the heated plate can be minimized. Another advantage the inventive method is that the Heating time of the pressure measuring device with about 2 to 3 Mi grooves significantly shorter than the heating-up time of an open is melt extruder.

As a covering for the inclusion of the blocks of material preferably a polymer film, for example a copolyamide foil used. This film material is with the usual Lichen hot melt adhesives very well tolerated, and with appropriate recipe design can by Foil material even the adhesive properties of the adhesive adhesive can be improved. Mixes when melting the film with the pressure sensitive adhesive completely without that environmentally harmful residues or vapors arise.  

The film is also characterized by a high Tensile strength resulting in increased stability of the wrapped blocks. In particular, a Verfor the blocks by cold flow of the mate rials avoided or mitigated.

The melting temperature of the film is around 120 to 150 ° C. At this temperature, most melt show pressure sensitive adhesives already have a fairly high fluidity. The adhesive can therefore be used immediately after manufacture poured into a mold lined with the film without the film being destroyed. It is optional also possible to use the pressure sensitive adhesive in a proportionate manner to extrude thick strand and which are separated from the strand cut blocks into a tubular, on both To seal the ends of the welded foil. Furthermore is it is conceivable to get the blocks in deep drawn or blown thin-walled vessels made of the film material or the like include material.

The size and shape of the blocks of pressure sensitive adhesive can vary vary in a wide range depending on the application. There the copolyamide film in turn melt-adhesive property ten has and the properties of the pressure sensitive adhesive not impaired, but rather improved, can Foil share in the total mass be relatively large. It is therefore conceivable to size the "blocks" on the Reduce the size of coated tablets coated with a copolyamide Wrapping are provided and processed like granules that can. On the other hand, there is an upper limit for the Size of the blocks practically only by the thermal loading resilience of the material and the cooling time during manufacture position set.

The thickness of the film depends on the size of the blocks gig and should be chosen so that the film when closing  the block did not pop up to the pressure melter tears before the actual pressure melting process begins. In practice, the film thickness is in the range of 0.02 to 3 mm, preferably 0.1 to 0.2 mm. The foil makes a single packing of the blocks during the trans ports and storage unnecessary. With sufficient Film thickness can possibly also be on a protective packaging dispensed with containers consisting of several blocks are so that the blocks ge on pallets, for example can be stacked and transported.

In the following a preferred embodiment of the Invention explained with reference to the drawing.

The only figure shows a vertical section through one especially for the implementation of the invention Process-equipped pressure melting device.

The pressure melting device 10 is essentially gebil det by a cylinder 12 , which has a rectangular cross section and at the lower end by a provided with outlet channels 14 from heated bottom plate 16 is closed ver. A piston 20 is movable in the cylinder 12 with the aid of a drive cylinder 18 . The underside of the piston 20 and the inner surfaces of the cylinder in the loading area of the lower end of the cylinder are lined with anti-adhesive. The piston forms a narrow gap with the cylinder walls. With the help of a control device, not shown, the stroke movement of the piston 20 is controlled and the temperature of the heated base plate 16 is statically regulated.

A side wall of the cylinder 12 is provided with an opening 22 which is closed in the lowered position of the piston 20 by a wall 24 projecting from the piston. On the outer wall of the cylinder 12 an inclined downward feed shaft 26 is attached, the open lower end of which is aligned with the opening 22 of the cylinder wall. A stop element 28 can be extended into the interior of the feed shaft 26 with the aid of an air cylinder 30 . A controller for the air cylinder 30 is coupled via cams, limit switches or the like to the movement of the piston 20 in such a way that the element 28 only releases the feed shaft 26 for a brief moment when the piston 20 is in the lowered position and the opening 22 is closed by the wall 24 .

The bottom plate 16 has a sawtooth-shaped profile on its inner surface, which is formed by a number of parallel grooves 32 which directly adjoin one another with their flanks. Each of the grooves is connected to one of the outlet channels 14 via bores 34 extending from the bottom of the groove. The outlet channels 14 are in turn ver via a transverse collecting channel 36 with a spout 38 formed on the underside of the base plate 16 .

The hotmelt PSA is supplied in the form of cylindrical blocks 40 via the feed shaft 26 . In the example shown, the blocks 40 have a diameter of approximately 20 cm and a height of approximately 20 cm. Each individual block is completely enclosed in an envelope made of a melt-adhesive copolyamide film with a thickness of about 0.1 to 0.2 mm. A suitable film is offered by Plate Bonn GmbH, among others, under the trade name "Platilon H 2 ".

When the piston 20 is in the raised position and the opening 22 clears, one of the blocks 40 rolls into the interior of the cylinder 12 , while the following block is retained by the stop element 28 . The block falls on the hot base plate 16 within the cylinder 12 . At the ribs formed between the grooves 32 , the film is locally melted, and the adjacent hotmelt adhesive is melted, so that a mixture of hotmelt adhesive and film material runs to the bottom of the grooves 32 . During the lowering movement of the piston 20 , the hotmelt pressure-sensitive adhesive is pressed firmly against the base plate 16 , so that the remainder of the film and the hotmelt pressure-sensitive adhesive are melted in direct contact with the base plate 16 and pressed out through the bores 34 , the outlet channels 14 and the outlet 38 .

Since the originally cylindrical block 40 with its circumferential wall rests on the base plate 16 , the film in the middle of the base plate 16 is melted off relatively quickly, so that there is only melted hotmelt adhesive. In the edge areas of the base plate 16 , on the other hand, part of the film lying on the peripheral wall and the end faces of the block is always melted during the entire melting process. In the lass channels 14 and the collecting channel 36 , the film and pressure sensitive adhesive components of the melt are mixed so that the melt emerging from the outlet 38 always has approximately the same composition. In the Absenkbe movement of the piston 20 , the block 40 is compressed so that it fills the entire remaining volume of the cylinder 12 . However, the film does not tear open, but rather forms a protective layer which lies against the inner surfaces of the cylinder and against the piston and prevents the pressure-sensitive adhesive from adhering to the cylinder and the piston.

Since the block of adhesive is pressed together by the piston 20 at the beginning of the lowering movement to form a cake, the melting zone is sealed practically airtight by the adhesive which has not yet melted, so that no reaction with the ambient air can occur. Since the film enclosing the hotmelt pressure-sensitive adhesive is only destroyed in the melting device, the adhesive remains in the absence of air until the actual melting process. The method according to the invention is therefore also particularly suitable for the processing of materials which react with oxygen or atmospheric moisture and are therefore difficult to handle otherwise. In particular, reactive polyurethane adhesives can also be processed.

When the piston 20 has reached its lowest position, the stop element 28 is withdrawn so that the next block 40 rolls against the wall 24 . Shortly after the start of the upward movement of the piston 20 , the impact element 28 is extended again. In this way it is ensured that only exactly one block 40 enters the cylinder 12 during each working cycle, and it is prevented that the film envelope of the subsequent block is damaged during the lowering movement of the piston.

The invention thus allows an inexpensive one Fast and safe processing of hotmelt PSAs and contributes to the solvent-free and thus be especially environmentally friendly hot melt adhesives develop areas of application.

Claims (7)

1. A method for melting thermoplastic or thermoset compositions, in particular hot melt pressure sensitive adhesive, in which the mass is entered with a covering in a melting device, characterized in that the mass is provided in the form of blocks ( 40 ), each individually are completely enveloped, and that for melting the blocks a Druckschmelzvorrich device ( 10 ) is used in which the blocks ( 40 ) with the envelope in a cylinder ( 12 ) with the aid of a piston ( 20 ) against one with outlet channels ( 14 ) heated bare base plate ( 16 ) are pressed. 2. The method according to claim 1, characterized records that the envelope of fusible Ma material exists. 3. The method according to claim 2, characterized records that the sheathing by a polymer film, for example polyethylene or copolyamide film educated. 4. The method according to any one of claims 1 to 3, characterized in that the blocks ( 40 ) have a flat cylindrical shape and are introduced into the melting device in such a way that they rest with their peripheral surface on the base plate ( 16 ). 5. A method for processing adhesive highly viscous masses, in which the mass to be processed with the help of egg nes piston ( 20 ) from a with an outlet ( 38 ) hen cylinder ( 12 ) is pressed, characterized in that the mass to be processed in Form of blocks ( 40 ) is provided, each of which is completely enclosed in an envelope, and that the blocks ( 40 ) with the envelope in the cylinder of ( 12 ) are entered. 6. pressure melting device for carrying out the procedural method according to one of claims 1 to 5, with a in a cylinder ( 12 ) displaceable piston ( 20 ), one of the cylinder bottom forming, provided with outlet channels ( 14 ), heated base plate ( 16 ) and Above the bottom plate ( 16 ) in the cylinder opening feed shaft ( 26 ), the mouth of which can be closed by the piston ( 20 ) in its lowered position, characterized in that at the feed shaft ( 26 ) at a distance from its mouth in the movement path of the blocks ( 40 ) before jumping, retractable stop element ( 28 ) is net angeord. 7. The device according to claim 6, characterized in that the distance of the stop element ( 28 ) from the mouth of the feed shaft ( 26 ) in the cylinder ( 12 ) is at least equal to the length of one of the blocks ( 40 ) and that a drive ( 30 ) is coupled to the movement of the piston ( 20 ) for the stop element such that the stop element is withdrawn during a certain time interval when the piston ( 20 ) is in the lowered position.