DE3003547A1 - DEVICE FOR CONTINUOUSLY TREATING MIXTURE FROM SOLIDS AND A THERMOPLASTIC BINDING AGENT - Google Patents

Description

Munich, January 31st, 1980 Lawyer file: 46 - Pat. 72

U. Ammann Maschinenfabrik AG, CH 4900 Langenthai / Switzerland

Device for the continuous preparation of mix Pesticides and a thermoplastic binder

The invention relates to a device for continuous processing of mixed material of solids and a thermoplastic binder according to the preamble of claim 1.

Facilities of this type are known to work as follows: The solids usually consisting of granular rock components are fed to one end of the rotating mixing drum by means of the feed device and in the first drum section promoted and scattered through the internals, whereby they are caused by the heat radiation of the flame of the one end face arranged burner and the hot gases generated by it are heated and dried. In the second drum section is the solids then the thermoplastic binding agent, for example bitumen, is metered in by means of the adding device and both are added mixed with one another by the mixing elements, preferably spreading vanes, the individual solid grains each with one be wrapped in a thin layer of binder. The ready-to-install mix thus formed enters the outlet chamber at the other end, the exhaust gases from the process are drawn off through the flue.

030039/0615

It has been shown that the flame radiation especially with certain Operating states, e.g. partial load operation or very forced operation, so strongly into the second drum section acts to damage or destroy the thermoplastic binder. In order to avoid this, so far between the first and the second drum section incorporated a round disc containing the binder located in the second drum section or shielded the mix from the flame.

The well-known shielding device had the technical part that the passage of gas in the area of the pane was also prevented, so the pane forced the hot gas to flow around the pane edge. The disc thus caused that around it, corresponding to the reduction in the clear drum cross-section, significantly increased axial gas velocities occurred, resulting in an extreme visual effect of the dry solids and thus increased dust discharge from the drum. In addition, a long flow dead zone was formed behind the disk in which the heat exchange between the hot gas and the mix as a result of the reduced relative speed between the there almost dormant gas and the spread mix has deteriorated.

The shielding devices used to date have thus provided the desired protective effect against direct irradiation of the mixture by the flame the disadvantages of increased dust discharge and reduced heat transfer from the hot gas to the Mixed material, i.e. a lower profitability.

The invention is based on the problem of, on the one hand, the thermoplastic To reliably protect the binding agent from flame radiation and, on the other hand, the heat transfer between the hot gas and to improve the mix and to reduce dust discharge.

The inventive solution to this problem is the subject of Claim 1. Preferred embodiments of the invention are

030039/0615

in claims 2 to 8 circumscribed.

By in the preferred embodiment of the invention according to claim 3 caused the slight damming effect of the gas flow, an axial flow velocity which is particularly uniform over the drum cross-section is achieved achieved.

In the following, with reference to the accompanying drawings, a known device for processing mixed material and exemplary embodiments thereon are first described the device according to the invention explained in more detail. Show it:

Fig. 1 is a schematic representation of a known device in longitudinal section,

2 shows a schematic representation of an inventive Establishment in longitudinal section,

3 shows a plan view in the direction of view from the drum inlet onto one half of one and the other half of another Embodiment of the shielding device of the device according to the invention shown in FIG. 2,

FIG. 4 shows a variant of the shielding devices shown in FIG. 3,

5 shows a perspective view of a further variant of the shielding device according to the invention with part of the Mixing drum,

6 shows a development of the circumference of the shielding device according to FIGS. 5 and

FIG. 7 shows a variant of FIG. 6.

The known device shown in Fig.l for processing

030039/0615

of mixed material has a mixing drum 1, which is slightly inclined from the inlet to the outlet, by running rings and rollers, not shown is supported and driven by means of a friction drive or chain. On one end face 2 are a burner 3 and a feed device 4 for granular solids, e.g. a feed chute or a conveyor belt. In the first section 1 'of the drum 1 are initially inclined conveyor blades 5 in the area of the feed device 4 arranged to convey the still moist solids towards the center of the drum in the drying zone. After that are so-called covered blades 6 mounted on the drum wall, which take up the solids but not into the Scatter the flame zone 8 in this area so that the combustion proceeds as undisturbed as possible. Then are Built-in spreading vanes 7, which spread a "solid curtain" which is as dense as possible when the drum rotates, so that the solids are removed heated by the flame radiation and hot gases and dried as completely as possible.

This first section 1 ^{f of} the drum 1, which is only used to heat the solids, is followed by the second section 1 ″, in which a device 10 for adding thermoplastic binding agent, for example bitumen, is guided Feed tube with one or more outlet openings.

Spreading vanes 7 are mounted on the wall of the second drum section 1 ″, which hold the solids wetted with the binding agent the hot exhaust gases repeatedly through the rotation of the drum sprinkle, the solid grains evenly with the binder and the mixture, which has become the mixed material, is further heated.

An outlet chamber closes on the other end face 9 of the drum 1 11 for the finished mix and a discharge duct 12 for the exhaust gases. The solids and the mix are pulled through

030039/0615

Arrows 13, the gas flow indicated by dashed lines and arrows 13 '.

In the known drum 1 according to FIG. 1, the two drum sections are 1 'and 1 "in cross section within the blades 7 separated from one another by a round disk 15, which is marked with (not shown) struts is attached to the drum wall. The disk 15 shields the second drum section 1 ″ from the Radiation of the flame 8, but causes the gases in the annular gap 14 between the disk 15 and the drum wall with large flow around the disk at an axial speed. The fines are made up of the at least almost dry solids extremely sifted out and increasingly discharged from the drum with the exhaust gas.

Behind the disk 15, a dead flow space 16 is formed in which the hot gases have almost no axial flow velocity and therefore only replace each other slowly. This is the relative speed between the gas and the scattered solids and thus also the heat transfer from the hot gas the solids in this area 16 are extremely small. Most of the hot gas flows with great axial speed along the internals 7 to the gas discharge duct 12 and leaves the drum at a relatively high temperature.

The device according to the invention according to FIG. 2 differs from the known device according to FIG. 1 by the design of the ^{shielding device arranged between the two drum sections I 1} and 1 ″. This consists of a radiation shield 18 attached to the drum wall by struts (not shown), which retains at least part of the flame radiation, but does not significantly impair the passage of gas.

The radiation shield 18, which - as shown in the left half of Fig. 3 - consists of a latticework 18a, e.g. a meshwork, or - as shown in the right half of FIG. 3 - from

030039/0615

can consist of a perforated plate 18b, causes a slight stowage of the gas flow in the first drum section 1 ', whereby the axial flow velocity is particularly uniform over the cross section will. But the jam effect is much less than that of the Washer 15.

The mesh 18a or the perforated plate 18b could also be in open Columns be arranged, whereby the cover against the flame radiation would be reinforced and the gas passage cross-section would be enlarged, which would lead to an even lower damming effect.

The gas flow flowing through the space 19 behind the radiation shield 18 is approximately the same over the entire cross section axial speed. This is also approximately the same or steadily decreasing over the entire length of the drum, so that the dry Pest substances are exposed to at most a low level of visibility and the dust discharge is reduced. This also includes the relative speed between the gas and the solids enveloped with the binder, falling through the gas over the whole Cross-section approximately the same size, so that in addition to reducing the dust discharge, maximum heat transfer is achieved will.

Because the radiation screen 18 at least part of the flame radiation is absorbed and thereby heated, the gas flow is also heated when flowing through the radiation shield, see above that the solids enveloped with the binding agent always fall through hot gas that is evenly heated by the radiation shield. this also contributes to the optimal, even heating of the mix.

The radiation screen made of / mesh 18a shown in FIG. 3 or the perforated plate 18b, does not shield the entire radiation of the flame, but allows a certain portion of the radiation to pass through pass through the gas passage openings (sieve gaps or holes).

030039/0615

The shielding device shown in Fig. 4, the individual, has baffles 28 inclined to the drum axis, the front edges 29 of which on the upstream side at least approximately in lie in one plane, on the other hand, when viewed in the axial direction of the drum, it covers the entire surface. In the axial direction they show Baffles 28 thus have a closed shape and one then speaks of a closed grid, which is at least theoretically the absorbs all radiation of the flame in the axial direction.

The inclined position of the guide plates 28 provides the gas passage guaranteed in parallel with them. This increases the relative speed between gas and solids and increases the heat exchange improved without increasing the axial velocity of the gas.

The fines entrained in the gas are increasingly directed across the spreading mix and covered by the binder Solid grains caught and bound.

This further reduces the discharge of dust and improves the heat transfer from the gas to the mix.

The shielding device according to Fig. 5 consists of many narrow, flat baffles 36, the front edges 31 of which are on the gas inlet side 32 lie in a plane perpendicular to the drum axis 33. But you could also form a flat cone. The baffles 36 are each at an angle oC from their front edges inclined by, for example, 30 ° to the drum axis 33 and represent a closed grid Guide plates 36 issued a strong twisting movement in the counterclockwise direction.

The guide plates 36 form a simple, fixed, axial guide wheel with flat guide surfaces. In the area of the plates 36 in the drum 1 no spreading vanes 7 but only lifting bars 35 are arranged, which the solid grains about up to half the drum

030039/0615

Take the heap with you and then let it unroll. This avoids that test substance grains fall on the sheets 36 and again get back into the first drum section 1 '.

At the same time, the lift bars 35 have the advantage that less dust is generated in the area of the shielding device, because the solids are not scattered into the gas stream there.

The sheets 36 can be seen in the axial direction partially overlap, as shown in the development of the umbrella perimeter in Fig. 6 is shown. The overlap area is denoted by U here .

The relative speed is determined by the strong swirling movement of the gas between the hot gas and the mix spread by the spreading vanes 7 is increased and the heat transfer is improved. Some of the fines contained in the gas are thrown out and some are moved several times across the falling mix so that they increasingly hit it and stick. This reduces the amount of dust discharged.

A shape of the metal sheets 36 which is particularly favorable in terms of flow is shown on the basis of the circumferential development in FIG. 7. The sheets 38 are aerodynamically optimally curved like an axial stator of a turbine or a fan in order to minimize pressure loss to effect. The guide surfaces 38 overlap, viewed in the axial direction, and form a closed grid. The leading edges 37 can lie in a plane or on a flat conical surface and the guide surfaces can twist from the outside towards the center in order to generate an almost constant twist over the entire cross-section.

Also shielding devices deviating from the forms described, e.g. shielding devices designed similar to slat blinds or ring nozzles, can be used. Z / RK / ms-6157 (3/12/79)

030039/0615

Claims (11)

DORNER & HUFNAGEL PATENT Attorneys LANDWEHRSTR. 37 8OOO MUNICH 2 TEL. O 89/59 67 84 Patent claims • Ί. Device for the continuous processing of mixed material made of plastics and a thermoplastic binder, with a rotating mixing drum, on one end of which a feed device for the pesticides and a burner are arranged, the flame of which generates a rectified hot gas flow, and on the other end of which there is an outlet chamber for the finished product Mixture and an exhaust duct for the exhaust gases are connected, with fixtures for conveying and scattering the solids being provided in the first drum section bounded by the one end face, an adding device for the thermoplastic binder being guided into the second drum section and mixing elements for mixing the solids with the binder being installed and a shielding device is provided between the two drum sections, characterized in that the shielding device (18, 18a, 18b; 28; 36) is designed so that it absorbs the heat radiation of the flame (8) of the burner (5) at least partially shields against the second drum section (1 »), but allows the hot gas flow (13 ¹ ) generated by the flame (8) and fine particles contained therein to pass through, so that the mix in the second drum section (1") is protected from the heat of the flame ( 8) is at least partially shielded, but the gas (13 ') can flow through the two drum sections (1 ·, 1 ") with approximately the same axial velocity component over the drum cross-section. 2. Device according to claim 1, characterized in that the shielding device (18, 18a, 18b; 28; 36) a plurality of uniformly Passage openings distributed over the drum cross-section Has. 030039/0615 3. Device according to claim 1 or 2, characterized in that that the shielding device (18, 18a, 18b) is designed so that a dynamic pressure on its front side in the flow direction in the gas flow (13 '), which is only a fraction of the dynamic pressure that occurs with a gas-impermeable shielding disk is. 4. Device according to one of claims 1 to 3, characterized in that that the shielding device (36) is designed so that it gives the gas flow (13 ') a swirling movement so that the Relative speed between the gas (13 ') and the material to be mixed increased, but the axial velocity component of the gas (13 ') is not increased. 5. Device according to one of Claims 1 to 3, characterized in that that the shielding device consists of a gas-permeable Radiation screen (18, 18a, 18b, 28) consists, which seen in the axial direction of the drum (1), at least part of the cross-sectional area the inside of the drum. 6. Device according to claim 5, characterized in that the radiation screen consists of a latticework (18a), for example a mesh (18a), or a perforated plate (18b), with the webs of the latticework (18a) or the plate (18b) part of the heat radiation catch the flame (8), while the intervening gaps in the latticework (18a) or. the holes of the perforated plate (18b) allow gas to pass through. 7. Device according to one of claims 1 to 4, characterized in that that the shielding device has individual metal sheets (28, 36) which are inclined to the drum axis (33) and are so dimensioned are that they show in the axial direction (33) of the drum (1) an at least approximately closed shape, so that the heat radiation running in the axial direction is shielded, while the gas flow (13 ') parallel to the metal sheets (28, 36) is unimpeded passes through. 030039/0 615 8. Device according to claim 7, characterized in that the front edges (29, 31) of the metal sheets (28, 36) in the flow direction lie at least approximately in one plane. 9. Device according to one of claims 4, 7 and 8, characterized in that that the shielding device has the form of an axial turbine or fan impeller (36). 10. Device according to one of claims 1 to 9, characterized in that that the shielding device (18, 18a, 18b; 28; 36) in cross section within the serving for spreading the pesticides Internals (7) is arranged. 11. Device according to one of claims 1 to 10, characterized in that the surface of the shielding device (18, 18a, 18b; 28; 36) is such that it absorbs at least part of the incident heat radiation from the flame (8), thus the gas flow (13 ^! ) is heated as it passes through the shielding device (18, 18a, 18b-; 28; 36) heated by the heat of absorption. RK / ms-6157
3/12/1979 030039/0615