Background of the Invention Elastomeric polymers of styrene and butadiene or isoprene are anionically polymerized in an organic solvent. Such polymers are also often hydrogenated while in the solvent. The final step in the production of these polymers requires removing the solvent from the polymer/solvent mixture/slurry/suspension, usually referred to as the polymer cement, to produce dry material which can be packaged. This final processing step is often referred to as"finishing"the polymer.

These polymers are generally produced as a crumb that is sometimes difficult to handle and is many times undesirably sticky as well. Problems associated with the adhesive nature of this sticky material put limitations on whether it can be realistically or profitably manufactured.

Even when it is realistically possible to manufacture these products, which are often sold in bags as crumb, the product's form can be difficult for endusers to handle and put to its desired use. Crumb particle size is often fine and it tends to coat equipment, particularly in the case of sticky grades, creating mess and waste. Some products block in the bags, forming a 13.6-18.1 kg (30 to 40 lb.)"pillow"of polymer. Bags of polymer must be cut open by hand and the blocked material has to be fed into a mechanical grinder prior to mixing with other ingredients.

Many polymers, especially thermoplastic but non- elastomeric polymers, are conveniently manufactured in pellet form. This form is very easy to handle and agglomeration problems can be easily solved by dusting the polymer with anti-stick agents. Pellets of these commercial thermoplastic polymers are formed with melt extruders, often twin screw extruders, which carry out their function by melting the polymer and extruding it through a die where it is chopped into small pellets.

Many of the polymers of this invention are high molecular weight materials and highly elastic materials. When these polymers are processed in twin screw melt extruders, they tend to generate enough shear heat to cause significant degradation. Degradation causes the polymer properties to suffer and is a significant disadvantage.

It is clear therefore that it would be highly advantageous to be able to finish the sticky elastomeric polymers of this invention in such a manner that they could be produced in pellet form. It would be most advantageous that this process be able to be carried out without significant polymer degradation.

Summary of the Invention This invention solves the problems discussed above.

Elastomeric anionic polymers of styrene and butadiene or isoprene, including polyisoprene star polymers, are anionically polymerized as in the past. This processing may also incorporate hydrogenation if desired. The polymer is produced in crumb form.

The dried polymer crumb is then converted to pellets via solid state extrusion. The polymer crumb is extruded in a single screw extruder which has a longitudinally grooved barrel and has pins extending into the barrel transverse to the flow of the polymer. The extruder has a length to diameter (L/D) ratio of 10: 1 or less,

preferably 8: 1 or less, and is operated at 30 to 100 rpm, preferably 40 to 60 rpm. The temperature of the polymer in the extruder must be sufficient to agglomerate or melt the polymer but the temperature should not exceed the degradation temperature of the polymer. Preferably, the solid state extrusion is carried out at 200 °C or less and most preferably 160 °C or less.

Detailed Description of the Invention It is necessary to use a single screw extruder in this solid state extrusion process in order to minimize shearing of the polymer. Excessive shearing can cause an undesirable increase in the temperature of the polymer which, as discussed above, can cause significant degradation. Twin screw extruders increase the shearing of the polymer and thus they may not be used in the present invention.

In this process, sufficient mechanical heat is generated by the polymer extrusion without auxiliary heating of the equipment or preheating of the crumb being necessary. Sufficient heat must be generated in order to agglomerate or melt the polymer sufficiently so that it can be extruded and then cut into pellets. By agglomerate, it is meant that the polymer is soft enough and sticky enough to stick together but has not yet passed through the glass transition temperature which is the point at which the polymer melts.

Polymers of the type described herein are known to degrade at temperatures of 300 °C and higher so it is important that the temperature in the single screw extruder be less than that. However, it is possible that higher localized temperatures can occur in the extruder so it is highly preferred that the temperature in the extruder be 200 °C or less. It is most preferred that the temperature be 160 °C or less to minimize localized

temperature peaks which can cause degradation of the polymer at those locations.

The use of a single screw (as opposed to twin screw) is necessary to get agglomeration without high temperature but it is important that sufficient mixing of the polymer occur. In order to make certain that this occurs, the barrel of the single screw extruder has longitudinal grooves and pins extending into the barrel transverse to the flow of the polymer. These features increase the mixing without dramatically increasing the shearing of the polymer.

The longer the time that the polymer is processed in the extruder, the more likely it is that degradation of the polymer will occur. Thus, it is preferred that long extruders not be used. It is preferred that the length to diameter (L/D) ratio be 10: 1 or less, preferably 8: 1 or less, most preferably 4: 1 or less.

In order to obtain sufficient mixing, the speed of the extruder screw should be from 30 to 100 rpm for extruders with an L/D ratio of from 2: 1 to 10: 1. If the L/D ratio is smaller, then the speed of the screw can be lower. Again, the goal is to provide sufficient mixing without heating up the polymers to a temperature where it degrades.

The polymers suitable for finishing by the process of this invention include hydrogenated homopolymers and copolymers of diolefins containing from 4 to 12 carbon atoms, hydrogenated copolymers of one or more conjugated diolefins and one or more monoalkenyl aromatic hydrocarbons containing from 8 to 16 carbon atoms. The base polymer may be of a star or linear structure.

Hydrogenated polymers may be hydrogenated selectively, completely or partially. Hydrogenated polymers of conjugated diolefins and copolymers of conjugated diolefins and monoalkenyl arenes are preferably

hydrogenated such that greater than 90% of the initial ethylenic unsaturation is removed by hydrogenation.

Preferably, the hydrogenated polymers are substantially free of ethylenic unsaturation.

Selective hydrogenation refers to processes that hydrogenate a substantial portion of the ethylenic unsaturation and a substantial portion of the initial aromatic unsaturation is left unhydrogenated. As used herein, a hydrocarbon polymer substantially free of ethylenic unsaturation will be a hydrocarbon polymer containing, on average, less than 10 carbon-carbon ethylenic double bonds per polymer chain. Polymers containing more than this amount of ethylenic unsaturation will, under certain conditions, exhibit excessive cross-linking during a functionalization reaction when the functionalization is completed in a blending apparatus capable of imparting high mechanical shear.

Useful hydrocarbon polymers include those prepared in bulk, suspension, solution or emulsion. As is well known, polymerization of monomers to produce hydrocarbon polymers may be accomplished using free-radical, cationic and anionic initiators or polymerization catalysts.

A wide range of molecular weight polymers can be processed as described herein. In general, the higher the molecular weight of the polymer, the more likely it is that degradation of the polymer will occur in conventional melt processing. Thus, this invention is especially advantageous for higher molecular weight polymers. In general,-polymers with weight average molecular weights of between 100,000 and 1,200,000 may be processed according to this process.

The weight average molecular weights, as used herein, for linear anionic polymers refers to the weight average molecular weight as measured by Gel Permeation

Chromatography ("GPC") with a polystyrene standard. For star polymers, the weight average molecular weights are determined by light scattering techniques.

EXAMPLES Comparative Example 1 To better understand melt extruder performance, several typical lab-scale rheological tests were performed. First of all, it was attempted to measure the melt flow index (MFI) of Polymer A, which is a hydrogenated polyisoprene star polymer containing 6% by weight polystyrene, at temperatures up to 270 °C. Even at these high temperatures and with weight as high as 9.9 kg, the material was extremely difficult to press through the melt flow die hole 0.2 mm (. 008 inch die).

Additional testing using a capillary rheometer at equally high temperatures yielded poor results. It was attempted to extrude Polymer B, another hydrogenated polyisoprene star polymer containing 6% by weight polystyrene, using a 19 mm (0.75 inch) Brabender single screw melt extruder heated to 200 to 220 °C and indeed some degradation did appear to occur. Twin screw extruders with their high shear mixing abilities might produce even more degradation.

Example 2 Several different polymer grades were agglomerated and pelletized in a 57 mm (2.25 inch) single screw extruder with attached Bodine motor adapted with cutter blades. The extruder had 6 grooves 9.5 mm (3/8 inch) wide and 1.6 mm (1/16 inch) deep longitudinal grooves in the barrel and 10 pins extending transverse to the flow.

Details of the extruder designs are shown in Table 1.

This extruder was utilized to determine if it was possible to agglomerate different elastomeric polymer crumb materials. Somewhat surprisingly, the extruder was easily able to produce pellets of many different such materials. In all testing, there was no evidence of polymer degradation in this type of extrusion.

Table 1: Single Screw Extruders example auger pitch compression L/D feeder Power diameter ratio (kJ/S) 2 57 mm 42.9 mm no 6 single paddle 2.2 (2.25 inch) (1.69 inch) compression packer 3 102 mm 102-76.2 mm 1.38: 1 4 twin paddle 11.2 (4 inch) (4 inch to 3 inches) packer

Unlike typical plastics extruders (melt), no additional heating of the extruder parts was utilized to accomplish agglomeration. The L/D ratio of the extruder is generally low in contrast to the typical L/D's of melt extruders that are in the range of 15-30. In addition, these single screw extruders deliver high torque at low RPM, thereby minimizing degradation due to shear heating.

The high torque capabilities allow them to easily process these highly elastic materials. The extruders tested have grooved barrels and pins. These two features ensure that material is uniformly sheared and therefore heated for agglomeration. Additional trials without grooves and pins were not as successful.

The 57 mm (2.25 inch) extruder was fitted with a variable speed cutter to pelletize the extruded strands.

Runs were carried out at 35 rpm. No external heating or cooling was applied. The temperature of the polymer due to frictional heating was 150 °C. All materials tested were extruded successfully with no degradation. It was more difficult to achieve a homogeneous strand with Polymer C which is a linear hydrogenated block copolymer of styrene and isoprene. Some strands appeared to have a "dust"of crumb along the outer edge indicating possible slippage along the barrel cavity and insufficient mixing.

This disappears as extruder temperatures rise.

Several KRATON materials were also extruded using the 57 mm (2.25 inch) unit (KRATON is a trademark). Research polymers KRATON GRP-6919 and GRP-6912, and commercial materials SHELLVIS 50,90,260,300 performed well (SHELLVIS is a trademark). Commercial polymers KRATON G1651, G1650, G1652, and research grade GRP-6917 were successfully pelletized after experimenting with different die designs. All of these polymers are manufactured by Shell Chemical Company and are block

copolymers of styrene and/or hydrogenated isoprene and/or butadiene.

Example 3 After the success of the 57 mm (2.25 inch) trials, the larger 102 mm (4 inch) extruder was used. Details of the extruder design can be found in Table 1. This extruder also had pins and grooves in the barrel.

Results proved equally successful. A large pelletization test run to produce approximately 1361 kg (3000 lbs.) of Polymer A was successfully performed. Typical run conditions were 35 rpm, 11.5 amps, and a production rate of 1.36 kg/min. (3 lb/min.) The 3.18 mm (1/8 inch) hole- size, 254 hole die was fitted with a two blade pelletier to cut the material as it was extruded. Pellets then fell into a small fluidized cooler. The cooler was equipped with a fan that delivered room temperature air at a rate up to 71 m3/min (2500 cu ft/min.). A temperature probe was placed approximately halfway down the barrel. The process appeared to reach steady state with a measured barrel temperature of 150 °C. This temperature is due to the shear heating of the material.

No external heating or cooling was applied. Pellets leaving the cooler were at a temperature of approximately 80 °C. No polymer degradation was observed in samples taken throughout the run.

Gel permeation chromatography analysis of crumb and extruded Polymers A and B from both of the extruders exhibits no signs of degradation. Polymer A and Polymer B were also tested in their intended use as an additive in motor oils. Both crumb and pellet forms were used. A comparison of rheological measurements of oil concentrates with crumb and pellet showed no change in the fundamental properties of the polymers with the extrusion.