SK8498A3 - Alleviating device - Google Patents

Abstract

A relaxation device for non-Newtonian fluids, comprises a cylinder (2) with an adjustable purging member (1) which moves along the fluid flow axis and creates a narrower flow cross-section than the area behind, along the flow direction. In a process for degassing non-Newtonian fluids involving multi-stage relaxation; a plastic melt is compressed between two relaxation stages, with an additive to aid extraction of volatile substances added in a mixer prior to the next relaxation stage. Pressure in the mixing zone is controlled by the claimed relaxation device, arranged between the mixing zone and the next degassing stage.

Description

Relief device

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a stripping device for structural viscous fluids and its preferred use for degassing plastic melts.

BACKGROUND OF THE INVENTION

The SRI Report "The SDS Polystyrene Process ShaoHwa Wang (PEP Review No. 90-2-3, Oct. 1991) discloses a two-stage process for degassing polystyrene melts. The two-stage degassing is effected by releasing from the melt pressure in the tanks at a pressure level decreasing step by step and serves to remove the monomeric styrene still present, the styrene oligomers and the polystyrene melt solvent. The melt coming from the polymer reactor is first pressurized, heated and released in the first stage tank, whereby some of the undesirable components are evaporated and drawn off. The polystyrene melt withdrawn from the first tank is then compressed again, topped up with water, gently permeated with water in the mixer and released again from the pressure in the second degassing tank. The water introduced between the stages and evaporating at the second pressure release serves as a stripping means for an improved removal of the undesirable components contained in addition to polystyrene in the melt in the second degassing stage.

The mixing of water or other additives into the plastic melt in such multi-stage degassing processes must be carried out at such high temperatures that the plastic melt remains liquid. In order to prevent the evaporation of the additives in the region of the mixing path through the use of high temperatures, a sufficiently high system pressure is required to keep all components in the liquid phase. This high pressure can be maintained in the mixing path, for example, by means of a deburring device in front of the closest deburring tank, the pressure itself being produced by a pump which transports the plastic melt against the deburring units at the outlet of the previous deburring tank. The release of the melt from the pressure is then carried out not in the nearest tank, but in the deburring device.

For Newtonian fluids, simple fittings that narrow the flow cross-section, such as valves or orifices, can be used as deburring devices. However, plastic melts often show a structurally viscous flowability, i.e. their toughness (viscosity) decreases with increasing shear rate. Also polystyrene melts are structurally viscous.

In order to increase the flow resistance of such a structurally viscous fluid, it is not sufficient to narrow the flow cross section only, so conventional relief members, such as valves or pressure-generating orifices, or pressure drop by a downstream valve, fail.

It is therefore an object of the present invention to provide a universally applicable deburring device for structurally viscous fluids, which is particularly useful in the multi-stage degassing of structurally viscous melts of plastics using additives.

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SUMMARY OF THE INVENTION

This object is achieved according to the invention by a structural viscous media deburring device according to claim 1, characterized in that it has a displaceable displacement body along the flow direction axis and an expanding flow cross-section in the displacement region of the displacement body.

in the direction

The discharge body and the inner geometry of the deburring device according to the invention are aligned in the region of displacement of the discharge body so as to obtain the necessary pressure drop.

The invention furthermore relates to a multi-stage process for degassing structurally viscous melts of plastics by means of a pressure release, in which the plastic melt is first compressed again at least between two stages and supplemented with an additive based on the principle of it regulates the pressure in the mixing path by means of a deburring device according to the invention, which is located between the mixing path and the nearest deburring stage.

In a preferred, very simple embodiment of the deburring device according to the invention, the device consists essentially of a piston / cylinder system as a displacement body and a housing.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is a schematic representation of a deburring device according to the invention.

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DETAILED DESCRIPTION OF THE INVENTION

The piston 1 is sized and guided in the heated cylinder 2 such that a circular gap is formed in the region a as the flow cross section for the flowing structural viscous fluid. Thus, the cross-sectional area of the flow is in this region and clearly smaller than in the remaining free flow channel. The length of the zone a, and thus the length of the flow channel in the zone a1, is narrowed as deeply determined by the cylinder 2. To change the depth, the plunger 1 of the plunger can be displaced by the adjusting mechanism.

3 ^. This also changes the friction surface prepared by the device according to the invention to a structural viscous fluid, which is necessary to build up the pressure (or pressure drop in the flow direction) by friction of the fluid against the wall.

The variable friction surface is formed by the outer surface in the region of the piston 1, and the structural inner wall surface of the viscous fluid of the cylinder 2 can be controlled throttled by the depth of plunger plunging into the cylinder 2. it also compensates for the effect of deteriorating toughness by increasing shear speed. The size of the annular gap, as well as the range of possible depth of immersion, must be dimensioned in the sizing of the device according to the invention using rheological data of the fluid and later operating conditions at throttling in order to achieve the desired throttling effect.

Otherwise, the flow, the change of friction as usual fittings that the relief device allows in the flow channel, throttling structurally changes according to the friction diameter of the invention wall area by changing

This allows surprisingly controlled viscous fluids.

Due to the shape of the components, the relief device according to the invention is not limited to rotary symmetrical piston / cylinder systems. Any other shaped displacement bodies and a casing adapted to them can be used, which leave a free adequate slot as a flow cross section and are longitudinally movable relative to one another. The slit as the flow cross-section need not be a circular slit, nor need it be constant over the entire displacement region of the displacement body, nor need it cover the entire circumference of the body. Thus, the device according to the invention can also operate, for example, on the basis of conical piston / cylinder systems, in which a displacement of the piston in the longitudinal direction also results in a simultaneous change in the flow cross section. The relieving device according to the invention can also serve as a shut-off element, whereby the conical surface and the end face of the piston are suitable as the sealing surface.

The guiding of the discharge body in the housing can be carried out in a manner known to the person skilled in the art, for example by means of several parallel keys or other projections or notches in the body and the housing, supported by the groove and tongue principle. To change the depth of immersion, the piston is in a preferred embodiment connected to a toothed rack along the axis of movement, which can be moved in the direction of movement by means of two pinions. In addition, however, various other adjusting mechanisms are also possible, such as spindle adjustment or other mechanical, electrical and / or pneumatic mechanisms.

The choice of material for the relief device of the invention for the process plants used uses according to as well as to the envisaged materials, in particular, when the viscous structural fluid is controlled by fluid conditions. Preferably, stainless steel nickel steel, high pressure and high temperature load.

sa like

Suitable fluids to be constricted are all structurally viscous fluids, for example silicones, spinning solutions, grease for Stauffer nipples, or even plastic melts such as polystyrene melts.

Depending on the melting point of the fluid, additional melting of the deburring device may be desirable.

For structurally viscous melts of plastics, the device according to the invention is preferably used in multi-stage pressure release degassing processes to remove unwanted components such as unreacted monomer, oligomers or polymer solvent. In particular, it is advantageous to use in multi-stage processes in which an additive is added to the melt between the individual stages in order to improve the degassing of undesirable components after release from the pressure. By means of a deburring device according to the invention, a pressure level can be maintained in the flow direction between the conveying pump at the outlet of the degassing tank of the previous stage and the relief device according to the invention before the next degassing stage to allow the addition of additives such as water to the melt, for example in mixers even at high temperatures (> 300 ° C), without premature evaporation of the ingredients. The position of the discharge body in the relief device may be controlled automatically by a pressure sensor located between the mixing device and the actual device. A particularly preferred device according to the invention for plastic melt.

is the use of degassing relief processes for

For use in such multi-stage pressure relief degassing processes, the relief device of the invention integrates directly into the pressure relief stage to increase the flow cross section in the flow direction at the fluid inlet to the tank. The fluid is then released from the pressure directly in the tank, for improved degassing.

Claims (9)

A relief device for a structurally viscous fluid device, having along (1) an adjustable flow increasing in the direction of the discharge direction of the displacement of the discharge body (1) in the flow direction. and cross section in the area Structural viscous fluid relief device according to claim 1, characterized in that the discharge body (1) is moved by means of a mechanical, electrical and / or pneumatic adjusting mechanism and fixed. The structural viscous fluid relief device according to claim 2, characterized in that the displacement body (1) is moved by means of a toothed rack and a pinion drive mounted thereon and fixed. 4. Relief device for structural viscous fluid according to at least one body is guided in a housing Relieving device according to at least one of the preceding claims, characterized in that the discharge device (2). for the viscous structural fluids of the preceding claims, in that the discharge body is a piston, a body which, with at least in the region of two bores moves through the diameters in the region of adjustment of the adjusting mechanism. and fixed by different pistons in a cylindrical internal aid 6. A process for degassing structurally viscous melts of plastics by means of a multi-stage pressure release, wherein at least between two stages the plastic melt is compressed again and is supplemented with an additive before the next pressure release, characterized in that the pressure in the mixing path by means of a relief device according to at least one of claims 1 to 5, which is located between the mixing path and the next degassing stage. Method according to claim 6, characterized in that the position of the discharge body (1) of the relief device in the adjustment region is controlled automatically by means of a pressure sensor which is located in the flow direction between the mixing device and the relief device. The method according to claim 6 or 7, characterized in that the plastic melt is polystyrene melt and the additive is water. Method according to at least one of Claims 6 to 8, characterized in that the relief device is integrated into the pressure release step.