DE4325849A1 - Flameproofed polylactide and copolylactide - Google Patents

Abstract

Flameproofed polylactide containing from 5 to 100 parts by weight of a metal oxide or metal oxide hydrate, phosphate or guanidinium salt per 100 parts by weight of polylactide.

Description

Polylactide is obtained by ring-opening polymerization of the cyclic Lactids manufactured. Starting from L-lactide, D-lactide or DL-lactide gives poly-L-lactide, poly-D-lactide or poly-DL- Lactide. In does not occur during the polymerization version on the optically active carbon atom, which increases the tacticity lasts. Poly-L- and poly-D-lactide can correspond to appropriate processing conditions, especially by briefly holding in Temperature range from 100-200 ° C as semi-crystalline polymers with a glass softening temperature of 50-55 ° C and one Crystallite melting point of 175 ° C can be obtained. By adding from DL or DD lactide or from DL or LL lactide to D lactide are copolymers with the ring-opening polymerization decreased crystallization rate and decreased obtained crystalline portion. The melting point drops that However, the glass softening temperature is retained. Would you like to however, lower the glass softening temperature, so you do one Copolymerization with the cyclic glycolide. The homopoly mere polyglycolide has a glass softening temperature of 20- 25 ° C. By copolymerizing appropriate proportions of lactide and glycolide the glass transition temperature of the copolymer accordingly Set between 20-25 ° C to 50-55 ° C.

By block copolymerization with longer chain cyclic Lactones, especially epsilon-caprolactone, are obtained in very tough form, impact-resistant lactide copolymers, which hardly differ distinguish reduced melting range.

Due to the excellent mechanical properties, the Conservation of resources, compostability and high Hydrolysis stability below 50 ° C has a high application potential. It can be used wherever it already is previously used engineering plastics, e.g. B. for housing or as functional parts in mechanical engineering, apparatus engineering, electronics technology, electronics and consumer goods industry. The application will only limited by the poorer weather resistance speed. However, wherever outdoor weathering or UV light does not occur The problem is, the parts are durable. Another The advantage of polylactide is its excellent leakage current strength, which is due to the fact that thermal No non-volatile aromatic, electrical pollution Conductivity-reducing degradation products are formed.  

Already not equipped polylactide shows in comparison to usual engineering plastics advantageous properties in Fire event: Due to the high oxygen content (approx. 44%) the heat of combustion is almost half that of usual plastics. Polylactide therefore burns at a lower rate Flame temperature than other plastics. The flame is barely there visible. Polylactide burns even without smoke and develops no coughing fumes. Until training yourself Constantly burning flame must be flamed much longer than for example in the case of polypropylene or polystyrene.

The object of the invention was to create the already inexpensive fire properties through the use of flame retardant additives improve that so treated polylactide after the fire behavior can be classified according to UL 94-VO.

Of course there is a big one to solve this task Number of commercial flame retardants such as halogenated longer chain alkanes, halogenated cycloaliphatic compounds, brominated diphenyls and diphenyl ethers, brominated polycarbonates, aliphatic and aromatic phosphorus compounds are available. Under the condition of disposal by composting ver however, the use of such flame retardants is appropriate.

It has now been found that polylactide is in the desired Can be equipped flame retardant if 100 parts by weight each Polylactide with 5 to 100 parts by weight of a metal oxide or hydrate such as aluminum oxide trihydrate (or aluminum hydroxide), Magnesium hydroxide or a phosphate such as ammonium polyphosphate be mixed.

Guanidinium salts are also suitable as flame retardants such as guanidinium phosphate, guanidinium sulfate or guanidinium carbonate. The guanidine fraction disintegrates during composting in ammonia and urea, which are further broken down bacterially. Any mixtures of the flame retardants mentioned can be used Means are used.

The grain size of the flame retardant should, for. B. at 0.5 to 100 microns, preferably 2 to 20 microns. Before being mixed in the means for removing adhering water expediently up to 180 ° C and possibly reduced pressure (i.e. under 1 bar absolutely) dried. The incorporation into the polylactide takes place according to usual procedures. So it is cheap, the flame inhibiting agents in a melt of the polylactide, with an extruder first given dry polylactide if supplied under argon, at 190 to 210 ° C and current  down the flame through another opening in the extruder housing inhibiting agent is added. It has proven to be beneficial proven to thereby strongly cool the melt avoid that the inorganic powder, for example by means of a heated conveyor, at temperatures from 150 to Be preheated to 180 ° C.

For the production of small quantities of flame retardant poly lactids, e.g. B. for testing purposes, it is also possible to use polylactide 2 to 10 times their volume in chloroform at room temperature to dissolve the desired amount of flame retardant in the solution mix in and then evaporate the solvent, for example by means of a rotary evaporator.

The polylactides used are preferably Poly-L-lactide or poly-D-lactide. Copolymers are lactides only of interest if they still have melting points above 150 ° C have, ie only up to about 5 mol .-% comonomer units. Comono mers are 1,3-dioxan-2-ones of the structure

1,4-dioxan-2-one of the structure

further lactides of the structure

or lactones of the structure

In the structural formulas mentioned, the radicals R¹ to R⁶ be the same or different and hydrogen, a branched or unbranched alkyl, alkylene or alkyne group with 1 to 12, preferably contain 1 to 4 carbon atoms, optionally by halogens, hydroxyl groups, alkoxy groups, formyl groups, Acrylic groups, amino, alkylamino, dialkylamino or cycloalkyl groups are substituted.

The homo- or copolymeric lactides are ring-opening according to the prior art based on the monomer melt at temperatures from 180 ° C to 230 ° C produced. BF3 etherate, titanium alcoholates and other man, zinc, tin, lead antimony or aluminum compounds can be used as polymerization catalysts. Tin-II compounds are most commonly used as carboxylic acid salts. Tin-II-octoate or tin-II-ethyl-2-hexanoate is preferably used in concentrations of 10 ^-6 to 10 ^-3 moles per mole of monomer mixture.

Examples

To demonstrate the effect, poly-L-lactide is treated with an in inherent viscosity of 1.59 (100 ml / g) measured as 0.1% Solution in chloroform at 25 ° C, used. The flame retardant Agents are mixed in by adding 50 g of additive in 300 ml Chloroform are suspended at 25 to 50 ° C and in this Suspe nsion 75 to 100 g of poly-L-lactide can be dissolved. After that it will Withdraw the chloroform in a rotary evaporator until the Mass is just still flowable. You will then be in a Poured polytetrafluoroethylene coated shell and the rest Chloroform at temperatures up to 100 ° C in a vacuum deducted drying cabinet. The material is removed with dry ice cools and granulated in a knife mill, dried and dried a die in a press at 200 ° C test rods of dimensions 1.58 mm (1/16 inch) x 12.7 mm x 127 mm. The test bars are clamped vertically and according to UL 94 of the Underwriter’s Laboratories tested and classified.  

Results

Claims (1)

Flame retardant polylactide containing on each 100 parts by weight of polylactide 5 to 100 parts by weight of one Metal oxide or metal oxide hydrate, phosphate or one Guanidinium salt.