ARTICLE COMPRISING MODIFIED TUBULAR LOW DENSITY POLYETHYLENE

Abstract

Process for obtaining polyethylene with an MFI (190° C./2.16 kg) of at least 4 g/10 minutes and a melt strength (190° C.) of at least 8.0 cN, said process involving extrusion of low density polyethylene (LDPE) with an MFI of at least 5 g/10 minutes and a vinyl content of less than 0.25 terminal vinyl groups per 1000 C-atoms (measured with NMR in deuterated tetrachloroethane solution)—in the presence of 500-5,000 ppm, based on the weight of low density polyethylene, of an organic peroxide.

Description

CROSS-REFERENCE TO RELATED APPLICATION

This application is a U.S. National-Stage entry under 35 U.S.C. § 371 based on International Application No. PCT/EP2018/082319, filed Nov. 23, 2018, which was published under PCT Article 21(2) and which claims priority to European Application No. 17204010.7, filed Nov. 28, 2017, which are all hereby incorporated in their entirety by reference.

TECHNICAL FIELD

The present invention relates to a process for the modification of low density polyethylene (LDPE) by reactive extrusion.

BACKGROUND

It is known to change the morphology and, consequently, the rheological properties of polyethylene by reactive extrusion in the presence of an organic peroxide. This leads to increased levels of long chain branching and, thereby, improved melt elasticity and improved melt strength.

US 2010/0076160, for instance, discloses the reactive extrusion of so-called ‘tubular LDPE’ to increase the long chain branching index.

LDPE is polyethylene having a density in the range 0.910-0.940 g/cm3 and is obtained by free radical polymerization of ethylene under high pressure. This process is either performed in an autoclave or in a tubular reactor. LDPE made by the autoclave reactor process (‘autoclave LDPE’) has a higher branching number than LDPE made by the tubular reactor process (‘tubular LDPE’). As a result, autoclave LDPE has a higher melt strength and is easier to process.

Commercial autoclave LDPE grades used for extrusion coating applications usually have an MFI (melt flow index) of at least 4 g/10 min. Lower MFI negatively affects the processability of the material.

The melt strength of autoclave LDPE with MFI≥4 g/10 min is generally 8.0 cN or more; whereas the melt strength of tubular LDPE with the same MFI is generally less than 8 cN. Melt strengths below 8 cN generally lead to inhomogeneous film thickness of the coating (high neck-in and poor draw-down).

Unfortunately, the autoclave process has a lower monomer conversion rate, requires higher capital investments, and has a poorer economy of scale than the tubular process. Hence, there is a desire to increase the melt elasticity and melt strength of tubular LDPE towards or even beyond that of autoclave LDPE of similar MFI.

This has been found possible by reactive extrusion in the presence of an organic peroxide.

Unfortunately, films obtained from reactively extruded LDPE tend to contain inhomogeneities, so-called gels. These are visual defects that transmit light differently from the rest of the material. Such gels consist of ultra high molecular weight polyethylene, formed by crosslinking. Gel formation leads to unacceptable aesthetic properties and to problems in printing and lamination processes; such as tearing of the film. Especially the lamination of LDPE cast film on cardboard—used to improve the barrier properties of e.g. drink packages—may suffer from film tearing at large gel-particles (typically above 600 μm).

Hence, there is a desire for a process for reactively extruding LDPE that allows for the manufacture of films with improved homogeneity, i.e. less visual defects. At the same time, the rheological properties of the resulting polyethylene should be about equal or better than that of autoclave LDPE. In addition, other objects, desirable features and characteristics will become apparent from the subsequent summary and detailed description, and the appended claims, taken in conjunction with the accompanying drawings and this background.

SUMMARY

It has now been found that gel formation can be significantly reduced by using LDPE with a low number of unsaturations, more in particular a low number of terminal vinyl groups. An even further improvement is achieved by optimizing the temperature and residence time in the extruder for the specific peroxide used.

The present invention therefore relates to a process for obtaining polyethylene with an MFI (190° C./2.16 kg) of at least 4 g/10 min and a melt strength (190° C.) of at least 8.0 cN, said process involving extrusion of low density polyethylene (LDPE) with an MFI of at least 5 g/10 min and a vinyl content of less than 0.25 terminal vinyl groups per 1000 C-atoms (measured with NMR in deuterated tetrachloroethane solution) with 500-5,000 ppm, based on the weight of polyethylene, of an organic peroxide.

DESCRIPTION

The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the invention or the following detailed description.

Low density polyethylene (LDPE) is polyethylene having a density in the range 0.910-0.940 g/cm3 and being obtained by free radical polymerization of ethylene under high pressure. In addition to ethylene, said LDPE may be obtained by using up to 10 wt %, preferably 0-7 wt %, and most preferably 0-5 wt % (based on the total amount of monomers) of co-monomers. Examples of such co-monomers include vinyl acetate, vinyl alcohol, acrylates, methacrylates, butyl acrylate, ethyl acrylate, acrylic acid, methacrylic acid, and C3-C10 α-olefins, such as propylene, 1-butene, 1-hexene, and 1-octene.

The LDPE to be modified according to the process of the present invention contains less than 0.25, preferably less than 0.20, more preferably less than 0.15, even more preferably less than 0.10, and most preferably not more than 0.08 terminal vinyl groups per 1000 C-atoms, as measured with NMR in deuterated tetrachloroethane (1,1,2,2-tetrachloroethane-d2) solution.

The types of unsaturation that can be present in polyethylene are terminal vinyl groups (R—CH═CH2), vinylidene groups (RR′C═CH2), and cis- and trans-vinylene groups (RCH═CHR′). The terminal vinyl content can be determined by 1H-NMR as described in the experimental section below.

LDPE with such low vinyl content is generally not directly obtained from an ethylene polymerization process. Instead, LDPE has to be subjected to a special treatment, such as hydrogenation or hydroformylation (as described is WO 2014/143507), in order to reduce the vinyl content.

In a preferred embodiment, the LDPE is extruded at a maximum temperature T, with a residence time tr, and in the presence of an organic peroxide with half-life t½ at temperature T (measured in monochlorobenzene), wherein tr/t½<400.

The maximum temperature during the extrusion is temperature T. If the extruder contains multiple zones with different temperatures, temperature T corresponds to the highest temperature that is applied.

Maximum temperature T preferably ranges from the melting temperature of the LDPE to be modified up to 240° C., more preferably 180-220° C., even more preferably 190-220° C., most preferably 190-200° C.

The residence time in the extruder (tr) is defined as 1.5 times the BreakThrough Time (BTT), which is determined by introducing a pigmented granule(s) in the mouth of the extruder and measuring the time required for a pigmented polymer melt to leave the extruder die. The residence time is preferably in the range 0.5-2 minutes. The ratio of the residence time and the peroxide's half-life at temperature T (tr/t½) is preferably less than 350, more preferably less than 300, even more preferably less than 250, even more preferably less than 200, even more preferably less than 150, and most preferably less than 100.

As illustrated in the Examples below, higher ratios may increase gel formation. Without being bound to theory, it is speculated that within the preferred ratio, transformation of alkyl radicals—formed after H-abstraction from LDPE by peroxide radicals—into allyl radicals is minimized. Allyl radicals pose a higher risk of gel formation than alkyl radicals.

The ratio of the residence time and the peroxide's half-life at temperature T is preferably more than 1, more preferably at least 5, even more preferably at least 10, and most preferably at least 15. Lower ratios may lead to residual peroxide in the polyethylene.

The half-life of the organic peroxide is determined by differential scanning calorimetry-thermal activity monitoring (DSC-TAM) of a 0.1 M solution of the initiator in monochlorobenzene, as is well known in the art.

Preferred organic peroxides are monoperoxy carbonates and peroxy ketals with a 1 hour half-life—measured with DSC-TAM as 0.1 M solution in monochlorobenzene—of 125° C. or below.

Particularly preferred peroxides include: 1,1-di(tert-butyl peroxy)-3,3,5-trimethylcyclohexane, 2,2-di(tert-butylperoxy)butane, 1,1-di(tert-butylperoxy)cyclohexane, 1,1-di(tert-amylperoxy)cyclohexane, butyl-4,4-di(tert-butyl peroxy)valerate, tert-butyl peroxy 2-ethyl hexyl carbonate, tert-amylperoxy-2-ethylhexyl carbonate, and tert-butylperoxy isopropyl carbonate.

In a preferred embodiment, the LDPE to be modified by the process of the present invention is tubular LDPE. Tubular LDPE is polyethylene made by free radical polymerization in a high pressure tubular process. The process according to the invention can modify said tubular LDPE into an LDPE with the quality of autoclave LDPE or even better (in terms of melt strength).

Preferably, the LDPE to be modified has a density within the range of 0.915 g/cm3 to 0.935 g/cm3, more preferably 0.918 g/cm3 to 0.932 g/cm3. The density can be measured according to ISO 1183/A.

The LDPE to be modified has a melt flow index (MFI)—measured at 190° C. and with a load of 2.16 kg—of at least 5 g/10 minutes, preferably 5-100 g/10 minutes, more preferably 5-60 g/10 minutes, even more preferably 8-60 g/10 minutes, even more preferably 10-60 g/10 minutes, and most preferably 10-40 g/10 minutes.

The LDPE to be modified preferably has a weight average molecular weight (Mw) of at least 100,000 g/mole. Such molecular weights are preferred for obtaining the desired melt strength. Mw can be determined with High Temperature Size Exclusion Chromatography (HT-SEC) as described in the experimental section below.

The organic peroxide can be added to the molten LDPE in the extruder, e.g. by liquid peroxide injection or by side feeding of peroxide blended in (LD)PE using a side extruder. Alternatively, solid LDPE (e.g. pellets, powder, or chopped materials) can be impregnated with organic peroxide prior to extrusion. The peroxide may be separately added to the hopper of the extruder by spraying or dripping the liquid peroxide or liquid peroxide formulation on the polyethylene.

The organic peroxide can be introduced as such, incorporated in an (LDPE) masterbatch or on a solid inorganic carrier (e.g. silica or kaolin), or dissolved or diluted in a phlegmatizer. Suitable phlegmatizers include linear and branched hydrocarbon solvents, such as isododecane, tetradecane, tridecane, Exxsol® D80, Exxsol® D100, Exxsol® D 100S, Soltrol® 145, Soltrol® 170, Varsol® 80, Varsol® 110, Shellsol® D100, Shellsol® D70, Halpasol® i 235/265, Isopar® M, Isopar® L, Isopar® H, Spirdane® D60, and Exxsol D60.

If desired—for instance to increase the ease of dosing—the organic peroxide can be even further diluted with a solvent. Examples of suitable solvents include the phlegmatizers listed above, or other common solvents, like toluene, pentane, acetone or isopropanol.

The organic peroxide is used in an amount within the range 500-5,000 ppm, more preferably 600-4,000 ppm, even more preferably 700-3,000 ppm, and most preferably 700-2,500 ppm, based on LDPE weight and calculated as neat peroxide.

Amounts significantly higher than 5,000 ppm may result in crosslinked polyethylene instead of long chain branched polyethylene. Crosslinking (gel formation) is evidently undesired.

The reaction of the polyethylene with the organic peroxide is preferably performed under inert (e.g. nitrogen) atmosphere.

The reaction is preferably performed in the absence of additional compounds containing unsaturations, as their presence would increase gel formation.

The modified polyethylene resulting from the process of the present invention has an MFI of at least 4 g/10 minutes, preferably in the range 4-15 g/10 minutes, and a melt strength of at least 8 cN.

This modified polyethylene has many applications. It can be used in extruded films, including blown films and cast films. It can also be foamed and/or thermoformed. The modified polyethylene can also be used in molding, including blow molding.

More importantly, it can be used in extrusion coating.

EXAMPLES

Determination of the Terminal Vinyl Content

50 mg of the polyethylene sample (powder or chopped material) together with 1 ml 1,1,2,2-tetrachloroethane-d2 (TCE-d2) were transferred into a 5 mm NMR tube. The NMR tube was purged with nitrogen gas and closed. The tube was placed in an oven at 120° C. to dissolve the polyethylene. After obtaining a clear transparent solution, the NMR tube was placed in the NMR spectrometer (Bruker Avance-IIIHD NMR spectrometer with a proton resonance frequency of 400 MHz using a 5 mm BBFOplus-probe).

Spectra were recorded at 120° C. Standard single-pulse excitation was employed utilizing a 30 degree pulse, a relaxation delay of 2.5 sec and 20 Hz sample rotation. A total of 750 transients were acquired per spectra. All reported chemical shifts were internally referenced to the signal resulting from the residual protonated solvent (TCE) at 5.98 ppm. The characteristic signals and chemical structures present are listed in Table 1.

TABLE 1
Group	Structure	1H chemical shift region	nH
Backbone chain	—(CH2)n—	0.50-2.80	2
Vinyl	R—CH═CH2	4.95-5.05	2
Vinylidene	RR’C═CH2	4.70-4.85	2
Cis/trans vinylene	RCH═CHR’	5.30-5.55	2

The amount of each unsaturated group (=Nunsat) was quantified using the integral (=Iunsat) of the group accounting for the number of reporting sites per functional group (=nH):

Nunsat=Iunsat/nH (Nunsat=Nvinylidene, Nvinyl or Ncis/trans)

The content of the unsaturated groups (Uunsat) was calculated as the fraction of the unsaturated group with respect to the total number of carbons present.

Uunsat=Nunsat/Ctotal

The total amount of carbon (Ctotal) was calculated from the bulk aliphatic integral between 2.80 and 0.50 ppm, accounting for the number of reporting nuclei and compensating for sites relating to unsaturation not included in this region.

Ctotal=(½)*(Ialiphatic+Nvinylidene+Nvinyl+Ncis/trans)

Example 1

Polyethylenes Used

Using the above described NMR technique, two commercial LDPEs were analysed for their degree of unsaturation. The results are reported in Table 2.

TABLE 2
	Unsaturation content/1000 C
			Cis/trans-
Sample code	Vinylidene	Vinyl	vinylene
LDPE-A (Sabic) MFI = 22	0.09	0.29	0.06
LDPE-B (ExxonMobil) MFI = 19	0.11	0.05	0.03

General Process Description

Low density polyethylene (LDPE) materials that were commercially available as powder (i.e. milled pellets) were used as such. In case only pellets were commercially available, the pellets were chopped by means of a Colortronic chopper equipped with a 3-mm sieve.

The peroxides—1,1-di(tert-butylperoxy)-3,3,5-trimethylcyclohexane (Trigonox® 29 ex-AkzoNobel) and tert-butylperoxy-2-ethylhexyl carbonate (Trigonox® 117 ex-AkzoNobel)—were dissolved in 30 ml pentane and formulated on 1300 grams of powder or chopped LDPE. Pentane was allowed to evaporate in a fume cupboard for approx. 4 hours and the LDPE/peroxide compounds were mixed.

The compounds were extruded on a Haake PolyLab OS RheoDrive 7 system fitted with a Haake Rheomex OS PTW16 extruder (co-rotating twin-screw, L/D=40), from Thermo Scientific, using following settings:

• • Three temperature profiles were tested: see Table 3
  • Screw speed: 150 rpm
  • Throughput: 1.5 kg/h, dosed by a Brabender gravimetric screw feeder type DDW-MD2-DSR28-10
  • Nitrogen was purged at the hopper (3.5 L/min) and at the circular die (9 L/min)
  • Residence time: 87 sec.
  • A screw configuration with two kneading sections was used: in zones 2-3 and 6-7, with a left-handed (i.e. reverse) element at the end of each kneading section

Table 3 presents the different temperature profiles used for the experiments on the PTW16 extruder.

TABLE 3
T-		Zone	Die
profiles	Hopper	1	2	3	4	5	6	7	8	9	10
180° C.	30	90	140	180	180	180	180	180	180	180	180
200° C.	30	90	140	180	200	200	200	200	200	200	200
220° C.	30	90	140	180	220	220	220	220	220	220	220

The extruded strand was led through a water bath for cooling and granulated by an automatic granulator.

The obtained granules were dried overnight in a circulation oven at 50° C.

Cast Film Preparation and Gel-Count Measurement

Cast film was prepared by extruding the obtained granules on a Dr. Collin Teach-Line E20T single-screw extruder, fitted with a Dr. Collin Teach-Line CR144T and CCD (Charged Coupled Device) camera for cast film preparation and gel evaluation. The following settings were used:

• • Temperature profile: 110-140-160-170-170° C. for zones 1 to 5
  • Screw speed: 50 rpm
  • Slit die approx. 8 cm, slit width 0.5 mm, gap between slit die and roll approx. 4 cm
  • Rolls were cooled with water at temperature of 25° C.
  • Film thickness of obtained cast films: 50 μm
  • Gel-count evaluation in different size ranges: <300 μm, 300-450 μm, 450-600 μm and >600 μm
  • Gel-count area: 1 m² film

Melt Flow Index

The melt flow index (MFI) was measured with a Goettfert Melt Indexer MI-3 according to ISO 1133 (190° C./2.16 kg load). The MFI is expressed in g/10 min.

Melt Strength

The melt strength (MS) was measured (in cN) with a Goettfert Rheograph 20 (capillary rheometer) in combination with a Goettfert Rheotens 71.97, according to the manufacturer's instructions using the following configuration and settings:

Rheograph:

• • Temperature: 190° C.
  • Melting time: 10 minutes
  • Die: capillary, length 30 mm, diameter 2 mm
  • Barrel chamber and piston: diameter 15 mm
  • Piston speed: 0.32 mm/s, corresponding to a shear rate of 72 s⁻¹
  • Melt strand speed (at start): 20 mm/s

Rheotens:

• • Acceleration of wheels (strand): 10 mm/s²
  • Barrel to mid-wheel distance: 100 mm
  • Strand length: 70 mm

Molecular Weight

The molecular weights of the LDPE samples were determined with High Temperature Size Exclusion Chromatography (HT-SEC) at 150° C. The triple detection system was calibrated using polystyrene standard 96K (Polymer Laboratories, Mw/Mn=1.03) in 1,2,4-trichlorobenzene at 150° C.

Each sample was dissolved in 1,2,4-trichlorobenzene (containing 300 ppm BHT), by heating at 160° C. under nitrogen atmosphere, for four hours.

A Malvern Viscotek HT-GPC system equipped with RI detector, LALS and RALS Light Scattering detector, and Viscometer was used.

Columns: A PL Gel Olexis Guard Column, 50×7.5 mm, 13 μm particle size, followed by three PL Gel Olexis 300×7.5 mm columns (13 μm particle size)
Mobile phase: 1,2,4-trichlorobenzene (Sigma-Aldrich, ReagentPlus, ≥99%), distilled, 300 ppm BHT added and eluent filtered through 0.2 μm PTFE filter.
Flow: 1 ml/min
Sample concentration: 3 mg/ml
Temperature: Autosampler and injector line heater at 160° C., and column/detector oven at 150° C.
Injection volume: 200 μl
Data processing: Omnisec™ v 4.61

Dn/dc for PE: 0.105

The molecular weights of the samples, i.e. the number-average (Mn), weight-average (Mw), and z-average (Mz) molecular weights, were calculated from Light Scattering (LS) detection.

Results

Table 4 presents the results obtained for the different LDPE materials, peroxides, and temperature profiles.

In Table 5, the molecular weights of the different LDPE materials are given, and the polydispersity is calculated as M_w/M_n, and M_z/M_w. It is noted that the higher M_z/M_w the more shear thinning the polymer is and the less energy input is required for obtaining the same extruder output.

The virgin LDPE's used had almost the same starting MFI (range 19-22) and mainly differed in their terminal vinyl content. Since each polyethylene application requires a specific MFI, it is important to reach similar MFIs after extrusion. In order to achieve this, different amounts of peroxide were required for each LDPE grade. LDPE with low vinyl content required higher amounts of peroxide.

TABLE 4
					MFI
				Gel-	@ 190°	Melt
		T-		count >	C./2.16	strength
	Peroxide and	profile	tr/	600 μm	kg (g/	@ 190°
	conc.	(° C.)	t1/2	(per l m2)	10 min)	C. (cN)
LDPE-B (=ExxonMobil LD600BA)-terminal vinyl content:
0.05/1000 C
virgin	none	none		20	19.0
blank	none	180		45	19.4
extruded		200		26	19.3
		220		24	18.8
modified	0.24%	180	19	35	8.0	10.9-11.3
	Trigonox 29	200	79	32	8.3	10.5-11.0
		220	290	57	8.4	10.2-10.4
modified	0.15%	180	16	84	7.7	12.5-14
	Trigonox 117	200	90	41	8.1	12.0-13.0
		220	435	188	8.3	n.m.*
LDPE-A (=Sabic 1922z500)-Comparative (terminal vinyl content:
0.29/1000 C)
virgin	none	none		11
blank	none	220		27	22.3
extruded
modified	0.16%	180	19	232	8.0	6.0-6.3
	Trigonox 29	220	290	596	8.7	n.m.
Autoclave LDPE
AC LDPE (=Ineos 19N430)	7.5	9.0
*n.m. = not measured

Table 4 shows that the reactive extrusion of a polyethylene with a low terminal vinyl content leads to melt strength values higher than that of autoclave LDPE, whereas reactive extrusion of polyethylene with high terminal vinyl content gave lower melt strength values.

The polyethylene obtained by the process of the present invention showed gel formation in cast film close to, or only a little higher, than that of the virgin material and of the same LDPE extruded without peroxide. In Table 4 this is shown for gel-particles >600 μm (which are the most critical particles for, e.g., extrusion coating), but the same effect was seen for smaller gel particles.

A higher terminal vinyl content resulted in modified LDPE with (extremely) high gel-count.

TABLE 5
	Peroxide	T-profile	Mn	Mw	Mz
	and conc.	( ° C.)	(kg/mole)	(kg/mole)	(kg/mole)	Mw/Mn	Mz/Mw
LDPE-B (=ExxonMobil LD600B A)-terminal vinyl content: 0.05/1000 C
virgin	none	none	11	118	426	11.2	3.6
blank	none	180	12	112	385	9.3	3.4
extruded		200	11	114	444	10.4	3.9
		220	12	112	396	9.3	3.5
modified	0.24%	180	17	196	1,053	11.5	5.4
	Trigonox 29	200	16	192	969	12.0	5.0
		220	16	191	952	11.9	5.0
modified	0.15%	180	15	213	1,216	14.2	5.7
	Trigonox	200	12	199	1,185	16.6	6.0
	117	220	14	209	1,136	14.9	5.4
LDPE-A (=Sabic 1922z500)-Comparative (terminal vinyl content: 0.29/1000 C)
virgin	none	none	10	77	226	7.8	2.9
modified	0.16%	180	13	118	476	9.1	4.0
	Trigonox 29	220	11	113	438	10.3	3.9
Autoclave LDPE
AC LDPE (=Ineos 19N430)	14	251	1,618	17.9	6.4

Example 2

Example 1 was repeated, except for (i) the nature of the LDPE's that were used and (ii) the screw configuration of the extruder.

The screw configuration used in the present example had three kneading sections—at zones 2-3, 4-5 and 7-8— with no reverse elements at the end of said kneading sections, thereby giving less torque during extrusion.

The T-profiles used were 180° C. and 200° C. (see Table 3).

Using the NMR technique described in Example 1, three additional commercial LDPEs were analysed for their degree of unsaturation. Results for all LDPEs used in this example are reported in Table 6.

TABLE 6
	Unsaturation content/1000 C
			Cis/trans-
Sample code	Vinylidene	Vinyl	vinylene
LDPE-A (Sabic) MFI = 22	0.09	0.29	0.06
LDPE-B (ExxonMobil) MFI = 19	0.11	0.05	0.03
LDPE-C (LyondellBasell)	0.20	0.32	0.08
MFI = 19
LDPE-D (Braskem) MFI = 20	0.21	0.08	0.14
LDPE-E (Ineos) MFI = 24	0.13	0.02	<0.01

Table 7 presents the results obtained for the different LDPE materials, peroxides, and temperature profiles.

In Table 8 the molecular weights of the different LDPE materials are given, and the polydispersity is calculated as M_w/M_n and M_z/M_w.

TABLE 7
					MFI
				Gel-	@ 190°	Melt
		T-		count >	C./2.16	strength
	Peroxide and	profile	tr/	600 μm	kg (g/	@ 190°
	conc.	(° C.)	t1/2	(per 1 m2)	10 min)	C. (cN)
LDPE-E (=Ineos 23T930)-terminal vinyl content: 0.02/1000 C
virgin	none	none		15	23.8
blank	none	200		24	23.2
extruded
modified	0.15%	200	90	56	8.4	19.0-20.5
	Trigonox 117
LDPE-B (=ExxonMobil LD600BA)-terminal vinyl content:
0.05/1000 C
virgin	none	none		12	19.0
blank	none	180		131	19.2
extruded		200		34	19.0
modified	0.24%	180	19	40	7.6	11.5-12.0
	Trigonox 29
modified	0.15%	200	90	52	7.8	11.7-12.2
	Trigonox 117
LDPE-D (=Braskem SPB208 Green LDPE)-terminal vinyl content:
0.08/1000 C
virgin	none	none		4	20.3
blank	none	200		20	20.2
extruded
modified	0.13%	200	90	71	8.2	15.5-16.5
	Trigonox 117
LDPE-A (=Sabic 1922z500)-Comparative (terminal vinyl content:
0.29/1000 C)
virgin	none	none		11
blank	none	180		50	22.9
extruded		200		48	22.8
modified	0.16%	180	19	236	7.2	6.5-6.7
	Trigonox 29
modified	0.135%	200	90	316	8.1	6.3-6.6
	Trigonox 117
LDPE-C (=LyondellBasell Lupolen 800S)-Comparative (terminal vinyl
content: 0.32/1000 C)
virgin	none	none		14	18.8
blank	none	200		57	18.3
extruded
modified	0.105%	200	90	289	8.2	5.9-6.1
	Trigonox 117
Autoclave LDPE
AC LDPE (=Ineos 19N430)	7.5	9.0

Table 7 shows that the reactive extrusion of LDPE with a low terminal vinyl content leads to melt strength values higher than that of autoclave LDPE, whereas reactive extrusion of LDPE with high terminal vinyl content gave lower melt strength values.

The gel content of LDPE having a low terminal vinyl content and modified according to the present invention was only a little higher than that of the same LDPE extruded without peroxide (blank extruded′). In Table 7, this is shown for gel-particles >600 μm (which are the most critical particles for, e.g., extrusion coating), but the same effect was seen for smaller gel particles.

For LDPE with high terminal vinyl content, the effect of peroxide modification on the gel-count was much larger, resulting in a modified LDPE with a very high gel-count.

LDPE-B extruded without peroxide at 180° C. had a higher gel-count than LDPE-B extruded at 200° C. This might be due to its higher melt viscosity at 180° C., resulting in higher shear and more LDPE deterioration than at higher temperature.

Surprisingly, extruding LDPE-B with peroxide at 180° C. gave significantly lower gel-count than extrusion at the same temperature without peroxide. A similar effect for LDPE-B was observed in Example 1 (see Table 4).

TABLE 8
	Peroxide	T-profile	Mn	Mw	Mz
	and conc.	(° C.)	(kg/mole)	(kg/mole)	(kg/mole)	Mw/Mn	Mz/Mw
LDPE-E (=Ineos 23T930)-terminal vinyl content: 0.02/1000 C
virgin	none	none	10	156	861	15.4	5.5
modified	0.15%	200	11	335	2,507	30.5	7.5
	Trigonox
	117
LDPE-B (=ExxonMobil LD600BA)-terminal vinyl content: 0.05/1000 C
virgin	none	none	11	118	426	11.2	3.6
blank	none	200	11	108	396	9.8	3.7
extruded
modified	0.24%	180	14	194	1,078	13.9	5.6
	Trigonox 29
modified	0.15%	200	14	201	1,099	14.4	5.5
	Trigonox
	117
LDPE-D (=Braskem SPB208 Green LDPE)-terminal vinyl content: 0.08/1000 C
virgin	none	none	10	151	1,095	15.2	7.3
modified	0.13%	200	10	241	1,987	24.1	8.2
	Trigonox
	117
LDPE-A (=Sabic 1922z500)-Comparative (terminal vinyl content: 0.29/1000 C
virgin	none	none	10	77	226	7.8	2.9
modified	0.16%	180	11	125	632	11.4	5.1
	Trigonox 29
modified	0.135%	200	11	130	679	11.8	5.2
	Trigonox
	117
LDPE-C (=LyondellBasell Lupolen 1800S)-Comparative (terminal vinyl content:
0.32/1000 C)
virgin	none	none	10	98	599	9.7	6.1
modified	0.105%	200	12	134	729	11.2	5.4
	Trigonox
	117
Autoclave LDPE
AC LDPE (=Ineos 19N430)	14	251	1,618	17.9	6.4

LDPE-E and LDPE-C had the same M_n, but M_w and M_z of LDPE-E was significantly higher than of LDPE-C. LDPE-E required much more peroxide (0.15% vs. 0.105% Trigonox® 117) to reach MFI 8. Nevertheless, it showed a much lower gel-count, which must be due to its lower terminal vinyl content.

While at least one exemplary embodiment has been presented in the foregoing detailed description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the various embodiments in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment as contemplated herein. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the various embodiments as set forth in the appended claims.

Claims

1-15. (canceled)

16. An article comprising modified tubular low density polyethylene having:

an MFI (190° C./2.16 kg) of at least 4 g/10 minutes;

a melt strength (190° C.) of at least 8.0 cN; and

a vinyl content of less than 0.25 terminal vinyl groups per 1000 C-atoms measured with NMR in deuterated tetrachloroethane solution.

17. The article of claim 16 wherein the MFI is from 5-100 g/10 minutes.

18. The article of claim 16 wherein the MFI is from 10-40 g/10 minutes.

19. The article of claim 16 wherein the MFI is from 4-15 g/10 minutes.

20. The article of claim 16 that is a blown film.

21. The article of claim 16 that is an extruded film.

22. The article of claim 16 that is a cast film.

23. The article of claim 16 that is a foam.

24. The article of claim 16 that is an extrusion coating.

25. The article of claim 17 that is a blown film.

26. The article of claim 17 that is an extruded film.

27. The article of claim 17 that is a cast film.

28. The article of claim 17 that is a foam.

29. The article of claim 17 that is an extrusion coating.

30. The article of claim 19 that is a blown film.

31. The article of claim 19 that is an extruded film.

32. The article of claim 19 that is a cast film.

33. The article of claim 19 that is a foam.

34. The article of claim 19 that is an extrusion coating.