DE4344845C1 - Pumpable hydrocarbon melts with low viscosity at 150 to 180 degrees centigrade - Google Patents

Abstract

The prodn. of pumpable hydrocarbon melts (I) with a low viscosity in the range 150-180 deg C comprises thermal degradations of high-mol. wt. polyolefins (II), by bringing (II) into contact with a melt consisting of cracking prods. of (II) at an autogenous temp. of 350-390 deg C in the absence of oxygen, and bringing this melt into intensive contact for at least 4 mins. with the heated (420-550 deg C) surfaces of a cracking reactor, with continuous thorough mixing, so that the temp. of the melt itself does not exceed 400 deg C. In the start-up phase, the hot melt is produced by adding solid polyolefin to a mixt. of high-boiling hydrocarbons in the cracker at 350-400 deg C. The melt temp. in the cracker is then controlled by adding solid polyolefin. The process can be carried out as a discontinuous process, or as a semicontinuous or continuous process by portionwise or continuous addition of polyolefin and portionwise or continuous removal of reaction prod..

Description

The invention relates to a method for gentle thermal Degradation of high-melting polyolefins, especially polyolefin waste that can no longer be used in materials.

In modern industrial society are growing in size Scope products made from polyolefins used, the are largely worked up after their use so that they can be used again in materials. So are Ver drive have been developed with which unmixed thermoplastic Plastic waste for reuse in the manufacture of Moldings are fed. Such a method is an example as described in DD-PS 1 37 938. Such a re However, use are due to an advanced material destruction and limits due to a high degree of pollution set.

Efforts have become known, but none of them more polyolefin wastes to be reprocessed under degradation their molecular structure for use as a chemical raw material feed. These procedures are either still in the Ent development stage or have so far been due to their high costs not sufficiently implemented in practice. It is therefore currently still widespread using such waste To burn energy content or to dump it in a landfill to lead.

A wide range of efforts so far to raw materials Recycling of polyolefin wastes use pyro processes lysis of the polyolefins with the aim of energy recovery the gaseous and liquid fission products. According to newer procedures is pre beat, thermoplastic waste by means of hydrogenation drive to mainly liquid and gaseous hydrocarbons refurbish. These procedures are usually based on the Foundation of the sump phase hydrogenation technology established. In doing so  the crushed plastic waste in the swamp phase with kata lyically acting solids mashed and with increased Pressures and temperatures until the plastic liquefies Pre-hydrogenated waste and then after separation of the solids contained in the liquid bottom product or subjected to multi-stage catalytic hydrogenation processes and in this way to liquid and gaseous hydrocarbon fabrics processed. These methods do allow environmentally friendly disposal of thermoplastic waste, but it requires a high level of technical effort and are therefore extremely expensive.

There has been no shortage of attempts, pure polyolefin Carefully process waste. For this purpose, DE-PS 30 37 829 described a method by which the production of modified Pitches and low-boiling aromatics or olefins through thermal Treatment of plastic waste in the presence of high-boiling Aromatics take place in such a way that the polyolefins at tempera structures above their decomposition point and pressures up to 830 bar with up to 90 parts by weight of aromatic boiling above 300 ° C Hydrocarbon mixtures under an inert gas atmosphere thermally be treated.

With the splitting of by-products from the production of polyethylene DE-B 24 19 477 also deals. Mixtures are and high molecular weight polyethylene waste products at 350 to 380 ° C cracked. These mixtures are substances which in contrast to the as thermoplastic plastics products on the market in this temperature range have a good pumpable consistency.

In the representation of the prior art in the DD-PS 1 34 773 a process for the production of olefin-containing light settle out of one in the production of polyethylene as a secondary product resulting mixture described. The are falling residues heated to about 400 ° C to the polyethylene waste in relatively low-boiling oils with high oil content, wax  and decompose soot. Here wax and soot must be discontinuous Lich removed from the reaction vessel.

DE-OS 26 23 331 proposes solid plastic-like Polyolefins in a mixture with 5 to 12 wt .-% of an inorganic Halide as a catalyst at a temperature of 150 to To keep 300 ° C in the molten state in this way win liquid and gaseous hydrocarbons. But these procedures also have in practice due to their high technological effort is of no importance.

Another possibility for the gentle processing of polyols Fin waste is described in DD-PS 2 00 891. After this Processes become polyolefin wastes, such as not more recyclable polyethylene, at temperatures dissolved in liquid hydrocarbons above 100 ° C and the a pumpable solution thus obtained is then a thermal Subject to treatment under normal conditions. That get Mixed substances either become one in the mineral oil subjected to normal recycling or without further processing Post-treatment for energetic use.

A disadvantage of the known methods is that they are not succeeds in solid polyolefin waste without the addition of external help convert substances into a liquid, pumpable consistency. This follows from the property of the polyolefins that they, up to to a temperature range around 400 ° C, in which clear, for sufficient splitting reactions begin the technical process, represent a highly viscous, technically difficult to handle mass. Although it is known to have a pumpable consistency by adding of suitable liquids, especially hydrocarbons mix to achieve, which, however, adversely affects the Economics of the process and the quality of the products obtained affects.

Another disadvantage of known methods is that Heating the liquid reaction medium to cracking temperatures  well above 400 ° C or by cracking in the gas phase mainly liquid and gaseous products are obtained, the Areas of application are narrowed accordingly. The extraction predominantly high-melting, solid fission products can with conventional methods cannot be achieved.

The invention has for its object the disadvantages of to eliminate known methods according to the prior art and to develop a process that is technically simple Gentle conversion of high molecular weight polyols to be realized fine, especially polyolefin waste, in a completely Fission products of the polyolefins existing and in the temperature range rich from 150 to 180 ° C still low viscosity, well pumpable Hydrocarbon melt allowed.

According to the invention, the object is achieved by a method in which the high-melting polyolefins, especially polyols Fine waste, with the exclusion of oxygen in one, in progress Process self-generated, 350 to 390 ° C hot melt from Polyolefin fission products are introduced and so ent mixture with cracking temperatures of 420 to 550 ° C heated reaction surfaces of the apparatus, such as heated outer walls, built-in heating elements or heated Tube systems, with constant mixing in intensive Is brought into contact. The driving style of the split reaction used tors is designed so that the temperature of the melt Does not exceed 400 ° C. This is expediently done by targeted addition of solid polyolefins in the running process. To this A reaction product is thus obtained, the solidification point of which is in the range of 80 to 150 ° C and at temperatures in the range from 150 to 180 ° C a thin, well pumpable Has consistency. The polyolefin particles become after and after entered into the melt, where it is due to the dissolve high temperatures in a few minutes. By the stand movement of the mixture causes the high molecular weight Polyolefins are split on the hot reaction surfaces. By preventing the melt from rising in temperature  400 ° C is a gentle splitting of the high molecular weight polyols fine reached. These are converted into a reaction product the predominantly from hydrocarbons of the C chain length range C₂₀ to C₇₀. The share of the distillate resulting light fission products is in the inventive Operation of the reactor in the range between 1 and 2 wt .-%. The gaseous gases formed during the reaction to a small extent Reaction products are advantageous for energetic use fed. As polyolefins such. B. LD, HD polyethylene, isotactic polypropylenes, mixtures with a predominant Share of such polyolefins and the like can be used.

The process according to the invention can be carried out batchwise or through portionwise or continuous addition of the polyolefin particles and portionwise or continuous removal of portions the melt formed as a reaction product semi-continuously or continuously.

According to a further feature of the Invention proved that benö for the approach of the method hot melt by introducing shredded polyols fin in high-boiling hydrocarbons at 350 to 390 ° C mixtures as they are common in the mineral oil and paraffin industries are, e.g. B. Paraffingatsch, in the splitters used to manufacture yourself. In this way, the use of strangers Hydrocarbons to an extremely low, only the start-up phase the minimum in question. The quality of the liquid gene reaction product is influenced only marginally. The reaction medium only exists during operation from crack products of the polyolefins used. This will the entry of external solution brokers avoided. The whole The capacity of the reactor stands for the gentle thermal Degradation of polyolefins available.

The method according to the invention makes this possible for the first time created high-molecular polyolefins, but especially accumulating in the economy to an ever increasing extent, not  more mechanically usable polyolefin waste, on simple Way without using catalysts or elevated pressures and thus avoiding expensive technology leading to high-quality raw materials for the mineral oil industry work up.

The invention is based on the following exemplary embodiments are explained in more detail.

1. In a 50 l stirred vessel provided with jacket heating 2 kg of a polyolefin obtained according to Example 4 fission products of existing reaction product with an Er filling point of 120 ° C and filled under inert gas sphere heated to 380 ° C. In the resulting low-viscosity The melt is chopped up at intervals of 10 minutes nert high-density polyethylene wastes from polyethylene bottles added in portions of 500 g each via a filling lock ben. Vigorous stirring will cause intense contact with the Mix with the reactor wall heated to 450 to 480 ° C reached.

This intense contact with the hot surface leads to one rapid cracking of the polyethylene molecules. This manifests itself also in that a occurring after the addition of waste and Visible increases in viscosity within the current consumption within dismantled in a few minutes.

As the filling volume of the reactor increases, the temporal Interval of adding the portions of waste to 4 to 5 minutes decreased. It also achieves that temperature the liquid despite the high jacket temperature 390 ° C rises, whereby the formation of short-chain gap pro products and a boiling of the reactor contents in favor of one homogeneous product is avoided.

After 40 kg of polyethylene waste within 7 to 8 hours have been filled, the content is cooled to 200 ° C.  

In this way, a reaction which is liquid at this temperature becomes product that has a solidification point of approx. 110 ° C having. The yield is based on the used Waste, at 95 to 98%.

2. In one with a jacket heater and with additional installation 100 l mixing vessel provided with heating surfaces becomes 40 kg of one filled reaction product obtained according to Example 4 and heated to 360 to 380 ° C. In the resulting melt are shredded at a speed of 15 kg / h Polyolefin waste consisting of a mixture of polyethylene high density (PE drums and canisters), lower polyethylene Density (PE film) and polypropylene, closed and under vigorous stirring analogous to Example 1 with the 480 to 500 ° C heated reaction surfaces brought into contact.

After filling and cracking 40 kg of waste, the reactor contents are stirred for a further 10 minutes. After that is half of the reaction product in one under inert gas standing template emptied. To what remained in the reactor Part of the approximately 380 ° C hot reaction product are again as described, added another 40 kg of waste. After that half of the reactor content is again removed and the reactor is loaded with waste again.

Through repeated alternate filling and product removal Continuous operation can be maintained with which one almost complete conversion of the waste into one at 180 ° C still fluid reaction product is achieved. This Product mainly consists of high-melting polyethylene fission products with an average melting point from 130 ° C.

The yield of solid cleavage product is 95% by weight. The shorter ones that resulted from the reaction in small quantities chain fission products and any occurring volatile decomposition products from foreign product buildup  the waste evaporates at the high reactor temperatures. The condensable components are connected in a downstream Radiator detected and amount to about 2 wt .-% of the use Waste.

3. In an apparatus consisting of one with a filler sluice feeder for the waste and a downstream heatable tube system a reaction product obtained according to Example 4 in liquid Form filled and circulated by means of a pump. The tube system is heated so that a wall temperature from 480 to 500 ° C is reached.

After the circulating melt has a temperature of 350 up to 360 ° C are shredded over the lock High density polyethylene waste (polyethylene drums and -canister) continuously entered into this melt. The resulting mixture is through the hot tube system pumped, thermally split there and then in two Partial streams separated. One part of the stream is in a cycle retracted into the feed tank and serves as Carrier medium for the waste to be brought in. The second Partial stream is fed from the circuit and leaves the apparatus as a reaction product with those in the examples 1 and 2 mentioned properties.

By regulating the addition of waste, by adjusting the flow speed in the tube system and through the choice of Wall temperatures in the tubes the process is controlled so that the mixture at about 350 to 360 ° C in the tube system occurs and this again with temperatures of 390 to 400 ° C leaves. After a stable driving style is achieved a continuous conversion of the waste into one at 150 ° C still pumpable reaction product.

4. In an apparatus according to Examples 1 to 3 is a standard filled, high-boiling paraffin gum and to 350  heated to 380 ° C. In this Gatsch, as in the Be play 1 to 3 described, the designated polyolefin waste fed and thermally split. By multiple Repetition of the process variant according to Example 1, be or by driving the equipment for a long time Example 2 or 3 becomes the Gatsch component in the reaction product gradually diminished and can eventually completely decline be relaxed.

Claims (4)

1. Process for the production of low-viscosity, well pumpable hydrocarbon in the temperature range from 150 to 180 ° C melt by thermal degradation of high molecular weight polyolefins, characterized in that the polyolefins are excluded from oxygen in a self-occurring 350 to 390 ° C hot melt in the running process Fission products of the polyolefins are introduced and this melt is brought into intensive contact for at least 4 minutes with surfaces of a fission reactor heated to 420 to 550 ° C. with constant mixing while avoiding an increase in the temperature of the melt mass to above 400 ° C. 2. The method according to claim 1, characterized in that the Production of the hot melt in the start-up phase Introducing solid polyolefins into high-boiling, 350 to 400 ° C hot hydrocarbon mixtures in the cracking reactor he follows. 3. The method according to claim 1 and 2, characterized in that that the temperature of the melt mass in the cracking reactor Addition of solid polyolefins is controlled. 4. The method according to claim 1 to 3, characterized in that the process is discontinuous or by portions or continuous addition of the polyolefins and portions wise or continuous removal of parts of the ent standing reaction product semi-continuously or continuously nuely designed.