UA135532U - Thermoplastic composite and multi-layer pipe made of it - Google Patents

Abstract

Thermoplastic composite of a copolymer of ethenyl acetate and ethenol with ethene with inorganic fillers and / or enhancers, containing 3-15% by weight of carbon fiber and up to 9.9% of basalt fiber.

Description

A utility model relates to thermoplastic composites based on a copolymer of ethenyl acetate and ethenol with ethene with inorganic fillers and/or reinforcements.

Thermoplastic composites are made with various organic fillers, such as wood flour, but mainly with inorganic fillers, the most common of which is calcium carbonate, and/or reinforcements, which mainly contain glass fibers and talc.

The use of inorganic fillers and reinforcements in thermoplastic composites is currently a common technology. However, if the fillers are really effective and significantly affect the mechanical and other physical properties, they can be used in concentrations of at least 20-30 95 by weight. This can be expensive, especially given the increased density of material filled or reinforced with inorganic substances.

The density of polyolefins, in particular polypropylene and polyethylene, as typical representatives, is usually in the range of 890-960 kg/m" and the density of inorganic fillers and enhancers is usually in the range of 2250-2600 kg/m3.

In thermoplastic composites, they usually try to improve the mechanical properties of the material. Other physical properties are less often attempted to be improved and/or modified. This can be, for example, a change in electrical properties. In this case, it is usually intended to reduce surface and/or bulk electrical resistance. Usually, one of the forms of carbon is used - highly conductive black carbon. Thermoplastic carbon black composites are used not only for electrically conductive elements, but also for heat transfer elements, usually in the form of pipes or containers, due to enhanced heat absorption or heat transfer placed in soil, water or air. The liquid - most often water - flows through heat exchange elements and thus transfers energy for further use, for example for heating buildings and water for technical purposes.

From other forms of carbon, you can consider carbon fiber. Its use as a plastic reinforcer is usually aimed at improving the mechanical properties of the resulting composite. The use of carbon fiber gives pipes with a reduced coefficient of linear thermal expansion, as already described in the Czech utility model Mo 27700 (submitted on 12.01.2015). Another physical property of plastic pipes is oxygen diffusion

From through the pipe wall into the transported liquid. The reduction of this diffusion is usually solved by the construction of a multilayer pipe containing a layer of polyethylene or polyamide. These polymers can be supplemented with layered fillers such as montmorillonite.

The task of the useful model is the development of a thermoplastic composite with a reduced coefficient of linear thermal expansion (hereinafter referred to as CLTR), used mainly for the production of pipes, which will at the same time form a barrier to the diffusion of oxygen through the wall of the pipe into the liquid to be transported.

The task is solved using a thermoplastic composite based on a copolymer of ethenyl acetate and ethenol with ethene with inorganic fillers and/or reinforcements, which, according to a useful model, contains from 3 to 15,956 by weight of carbon fiber and up to 9.9 95 of basalt fiber.

From a dosage point of view, it seems advantageous to use chopped carbon fiber.

From a recyclability point of view, it seems advantageous to use ground carbon fiber.

As for reducing the CLTR, this is aimed at a pipe that contains carbon fiber in at least one layer that forms the middle layer in a three-layer pipe.

Materials for internal water distribution are usually based on polypropylene and its copolymers with ethene. Copolymers can be heterophasic or random.

Polypropylene homopolymer is also used.

Since polyethylene and its copolymers with ethenyl acetate are chemically polar polymers, and materials based on polypropylene and its copolymers with ethene are chemically polar polymers, modification of one or the other or both polymers must be avoided to prevent separation of layers in multilayer pipes, so-called delamination. The modification is carried out with the help of a grafted polar comonomer, for example maleic anhydride. In this case, the content of the modified copolymer ranges from 15 to 35%.

The advantage of thermoplastic composite and pipes made from it is cost savings in the construction of pipeline systems. This saving is achieved by reducing the CLTR. pipes and, thus, reducing the number of temperature expansion compensators in the pipeline system and the number of connecting fittings. Another advantage is, in the case of the use of polyethylene and its copolymers with ethenyl acetate, the reduction of oxygen diffusion through the pipe wall into the transported medium (usually water).

A useful model is explained in detail using a drawing showing a cross-section of a multilayer pipe.

Implementation examples

Thermoplastic composites are mainly considered to contain composites based on polyethylene and its copolymers with ethenyl acetate with inorganic fillers and reinforcements.

Fillers in this useful model correspond to inorganic or organic particles with close to spherical symmetry, such as finely ground calcium carbonate, wood flour, or glass beads. In commonly used quantities, in this case, reinforcements mean inorganic or organic particles with close to flat or fibrous forms, for example, glass fibers, basalt fibers, carbon fibers, wollastonite, mica or talc. Again, unless otherwise specified, in generally defined amounts, as well as additives, hereafter are meant thermo-oxidative stabilizers, anti-ultraviolet stabilizers, lubricants, pigments and dyes, anti-spray additives, , acid scavengers, fillers and dispersing reinforcements (eg graft copolymers and modified waxes), agents for bonding fillers and/or reinforcements to a thermoplastic matrix (eg silanes) and the like.

Samples in the form of pipes are measured in the direction in which the production of the pipe takes place, that is, in the longitudinal direction.

Measurements are made in the standard version on a 15 mm test body body, made from the working part of a multi-functional test body, which has been dimensionally stabilized by hardening for 7 days at 95"s.

The used OMA OHT04 equipment (EMI SK company) allows you to carry out measurements by placing the test body in a working environment under pressure and applying a constant pressure of 4 kPa. During the temperature scan, measure the change in AL from the initial height of Po's body.

After adjustment on the basis of measurement experience, the measurement conditions are chosen as follows

Method: heating up to 95 °C at a speed of 3 °C/min., duration 20 min. cooling to 20 "C at a speed of 1 "C/min., recording every 0.5 "C, duration of 20 min. heating to 95 "C at a speed of 1 "C/min., unspecified duration of cooling to 20 "C at a speed 10 "S/min., END in-vo te (t 23 zurosti Ddp-p-pO close to the line:

The evaluation is performed both in the case of the first cooling of the sample and in the case of the second heating. The values are compared and the average value is calculated for each material.

The changes in the length 1 of the test bodies relative to the temperature are evaluated. Lok is calculated from these changes; 1 av 1 Al of thermal expansion: with pat n AT, where the deviation calculation is replaced by a local line that corresponds to five consecutive corrected points. Calculations are performed both in the case of the first cooling of the sample and in the case of the second heating.

The values are compared and averaged for each material.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. It is expressed in units of mg/m2.day.

The following examples illustrate samples of a multi-layer pipe made of composite according to a useful model.

Example 1

A selective copolymer of propene and ethene with the following characteristics was used as the main thermoplastic matrix: - melt flow rate 0.25 (g/10 minutes), (230 "C, 2.16 kg), (IBO 1133), - ethene content 5 95 per by mass, - density 902 kg/m3 (OR 1183/A).

This plastic was modified by melt compounding 1595 wt.m. of polypropylene modified with a polar comonomer. In this case, the plastic showed the characteristics shown in Table 1.

Table 1

Characteristics of polypropylene modified with polar comonomer type 1. (G/10 minutes),

Melt flow index IBO 1133 230 "С, 2.16 kg) 0.5 . . . Selective copolymer

Initial (main) plastic of propene with ethene 2, maleic anhydride of the embedded monomer

Acceptable way, . infrared

Content of grafted. o Spectroscopy on uo by the mass of 2 elements: based on the Fourier transform

A polymer containing these structural units in the main linear chain (hereinafter referred to as

RMON), also used in the production of a multilayer pipe: - ethene, - ethenyl acetate, - ethenol.

Table 2

Characteristics of the RUON 1 polymer

Melt flow index of IBO 1133 (G/L10 minutes), (190 "C, 2.16 kg)

IZO 1183-3 1180

Melting point (MO) ISO 11357

Glass transition temperature (О5С) IOLI357 s 71111116

From RMON, a thermoplastic composite (designated as RUONKOMRI) was obtained with Z 95 by weight of carbon fiber with the parameters listed in Table 3.

Table C

Characteristics of cut carbon fiber

Fiber surface treatment

Fiber diameter (μm)

Length of fibers before compounding (mm) in

Carbon content (95 by weight)

From a thermoplastic composite with C 956 by weight of carbon fiber, according to the Table

C, a three-layer pipe with the dimensions indicated in Table 4 was obtained. The cross-section of such a pipe is schematically shown in the drawing, where the thermoplastic composite is only in one layer 2.

Table 4:

Dimensions of a three-layer pipe

Outer diameter (mm)

Inner diameter (mm)

Total wall thickness (mm)

Continuation of table 4

Thickness of the outer layer - statistical copolymer of propene and ethene (mm)

Thickness of the middle layer - RUONKOMRI composite (mm)

Thickness of the inner layer - statistical copolymer of propene and ethene (mm)

Using the above-mentioned procedure, the coefficient of linear thermal expansion (LCER) was measured and it reached a (105/SI : 18.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to ISO 17455: 2005. Is it expressed in units of mg/m? day and it reaches 0.22 mg/m? day.

Example 2

The procedure according to example 1 was applied, with the following differences

Tables 5 and 6

Table 5

Characteristics of polypropylene modified with polar comonomer type 2. (G/10 minutes),

Melt flow index IBO 1133 230 "С, 2.16 kg) 4.5 . . . Selective copolymer

Initial (main) plastic of propene with ethene 2, maleic anhydride of the embedded monomer

An acceptable way to

Content of grafted infrared o element spectroscopy based on 5 by mass o, Fourier transform

A thermoplastic composite of 1595% by mass of chopped carbon fiber with the parameters given in Table 6 was made from RMON and is referred to as RUONKOMRI2.

As a binder, polypropylene grafted with maleic anhydride (Characteristics in Table 5) was added to the unmodified polypropylene material (selective copolymer of propene and ethene), as already described in Example 1 in a volume of 50 95 by weight.

Table 6

Properties of chopped carbon fiber

Fiber surface treatment

Fiber diameter (mm)

Fiber length before compounding (mm)

Carbon content (95 by mass) 1198

A three-layer pipe with given dimensions, identical to those specified in

Table 4. The cross-section of such a pipe is schematically shown in the drawing, where the RUONKOMR2 composite forms the central layer 2, see Table 5.

Using the procedure specified above, the coefficient of linear thermal expansion (CLTR) was measured and it reached a (106/"С1 - 15.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to ISO 17455: 2005. Is it expressed in units of mg/m? day and it reaches 0.42 mg/m? day.

Example C

The procedure was applied according to example 1, with the difference that a propene homopolymer with the following characteristics was used as a thermoplastic matrix: - melt flow index 0.30 (g/10 minutes), (230 "C, 2.16 kg), (IBO 1133 ), - density 905 kg/m3 (ISO 1183/А).

Using the procedure specified above, the coefficient of linear thermal expansion (LCER) was measured and it reached a (106/"С1 - 32.

Oxygen permeability is measured in accordance with IM 4726: 2008 with reference to I5ZO 17455: 2005. It is expressed in units of mg/m7.day and it reaches 0.62 mg/m-.day.

Example 4

The procedure was applied according to example 1, with the difference that a heterophase copolymer of propene and ethene with the following characteristics was used as a thermoplastic matrix: - melt flow index 0.25 (G/10 minutes), (230 "С, 2.16 kg), (IBO 1133), - ethene content 7 95 by mass, - density 900 kg/m3 (IBO 1183/A).

The plastic was modified by melt compounding 35595 by weight of polypropylene modified with a polar comonomer.

Using the procedure indicated above, the coefficient of linear thermal expansion (LCER) was measured and it reached a (106/"SI - 46.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. Is it expressed in units of mg/m? day and it reaches 1.02 mg/m2 day.

Example 5

A selective copolymer of propene and ethene with the following characteristics was used as the main thermoplastic matrix: - melt flow index 0.25 (G/10 minutes), (230 "С, 2.16 kg), (ISO 1133), - ethene content 5 95 per by mass, - density 902 kg/m3 (OR 1183/A).

The material was used for the production of a multilayer pipe, as indicated in the drawing. There, the material creates layers 1 and 3.

A polymer containing these structural units in the main linear chain (hereinafter referred to as

RMON), also used in the production of a multilayer pipe: - ethene, - ethenyl acetate,

Zo - ethanol.

Table 7

Characteristics of polymer RUON 2 (GL10 minutes), (190 "С, 2.16 kg) (Temperature glass transition (05С) | I5O11357. | С | 60

From RMON, a thermoplastic composite (designated as RMONCOMRZ) was obtained with 10 95 by weight of carbon fiber with the parameters given in Table 8.

Table 8

Characteristics of the RMON composite (RMONKOMRZ) modified with polar comonomer type 1

Melt flow index (g/L/min), ratio of propene with ethene 13303101 of plastic in composite 2, Maleic anhydride

Modifications 010000

Be ssnsssspya PENYA PINENNNNN SSV. cleaved branches of the modified comonomer

Continuation of table 8

An acceptable way to

The content of the grafted infrared element in the modified | spectroscopy on Fo by mass 10 plastic based conversion

Fourier

The content of carbon fibers

A three-layer pipe with the dimensions specified in Table 9 was made from RMONKOMRZ thermoplastic composite with 1095 by weight of carbon fiber, according to Table 8.

The section of such a pipe is schematically shown in the drawing, in which the thermoplastic composite is only in one layer 2.

Table 9

The dimensions of the three-layer pipe according to Example 5

Outer diameter (mm)

Inner diameter (mm)

Total wall thickness (mm)

Thickness of the outer layer - statistical copolymer of propene and ethene (mm)

Thickness of the middle layer - RMONKOMRZ COMPOSITE (mm)

Thickness of the inner layer - statistical copolymer of propene and ethene (mm)

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached a |105/С - 21.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to ISO 17455: 2005. Is it expressed in units of mg/m? day and it reaches 0.72 mg/m? day.

Example 6

The procedure according to example 5 was applied, with the difference that there was used crushed carbon fiber with the characteristics indicated in Table 6.

A thermoplastic composite (designated as

RMONKOMRU) with 10 95 by weight of carbon fiber with the parameters specified in Table 10.

Table 10

Characteristics of the RMON composite (RIUONKOMRAIU) modified with a polar comonomer of type 1. (G/10 minutes),

Melt flow index RMON |I5BO 1133 230 C, 2.16 kg), 0.5 propene with ethene 2, Maleic anhydride. cleaved branches of the modified comonomer

Acceptable

Vmi method, infrared-bridge of the grafted element in Lo and it spectroscopy| 96 by weight of 5 modified plastic - based on the Fourier transformation

The content of carbon fibers

A three-layer pipe with the dimensions specified in Table 9 was made from the RMONKOMRA4 thermoplastic composite with 1095 by mass of carbon fiber, according to Table 5.

The section of such a pipe is schematically shown in the drawing, in which the thermoplastic composite is only in one layer 2.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (LCER) was measured and it reached a | 105/SI: 12.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. It is expressed in units of mg/m7.day and it reaches 0.95 mg/m-.day.

Example 7

The procedure was applied according to example 5, with the difference that polypropylene homopolymer was used, exactly as specified in Example 3.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached a (10/21 - 27.

Oxygen permeability is measured in accordance with IM 4726: 2008 with reference to IBO 17455: 2005. It is expressed in units of mg/m7.day and it reaches 0.89 mg/m-.day.

Example 8

The procedure was applied according to example 5, with the difference that a heterophase copolymer polymer, exactly as specified in Example 4, was used there.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached a (106/"SI - 32.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. It is expressed in units of mg/m.day and it reaches 1.09 mg/m-.day.

Example 9

The procedure was applied according to example 5, with the difference that basalt fiber was also used in the middle layer at a concentration of 7 95.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (LCER) was measured and it reached a (105/SI : 54.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. It is expressed in units of mg/m7.day and it reaches 1.75 mg/m-.day.

Example 10

The procedure was applied according to example 6, with the difference that basalt fiber was also used in the middle layer at a concentration of 7 95.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached a (106/"С1 - 30.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. It is expressed in units of mg/m.day and it reaches 2.05 mg/m-.day.

Example 11

The procedure was applied according to example 7, with the difference that basalt fiber was also used in the middle layer at a concentration of 9.9 9.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (LCER) was measured and it reached a (105/SI : 18.

Oxygen permeability is measured in accordance with IM 4726: 2008 with reference to I5ZO 17455: 2005. Is it expressed in units of mg/m? day and it reaches 1.09 mg/m2 day.

Example 12

The procedure was applied according to example 8, with the difference that basalt fiber was also used in the middle layer at a concentration of 9.99.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached a (106/С1 - 21.

Oxygen permeability is measured in accordance with IM 4726: 2008 with reference to ISO 17455: 2005. Is it expressed in units of mg/m? day and it reaches 1.19 mg/me day.

Example 13

The procedure was applied according to example 9, with the difference that in the middle layer a modifier was used, as indicated in Table 5, in a concentration of 35 95.

Using the above-mentioned procedure, the coefficient of linear thermal expansion (CLTR) was measured and it reached sa (105/"SI - 38.

Oxygen permeability is measured in accordance with 0IM 4726: 2008 with reference to I5O 17455: 2005. Is it expressed in units of mg/m? day and it reaches 2.09 mg/m2 day.

Industrial suitability

The technological solution is suitable for the production of plastic pipes or other elements of pipelines made of polypropylene or its copolymers with ethene with a reduced coefficient of linear temperature expansion and reduced oxygen permeability.

It can also be used in the manufacture of co-extruded tubing for pressure and non-pressure applications.

It can also be used in the production of boards or foils, mainly co-extruded boards (two- or three-layer).

Claims (4)

USEFUL MODEL FORMULA 1. A thermoplastic composite of a copolymer of ethenyl acetate and ethenol with ethene with inorganic fillers and/or reinforcements, characterized in that it contains 3-15 95 by weight of carbon fiber and up to 9.9 95 of basalt fiber. 2. Thermoplastic composite according to claim 1, which differs in that the carbon fiber is cut. C. Thermoplastic composite according to claim 1, characterized in that the carbon fiber is ground. 4. Thermoplastic composite according to any one of claims 1 and 2, which is characterized by the fact that it contains from 15 95 to 35 95 by weight of a binder based on polypropylene and its copolymers with ethene and polar comonomers. Co. Я и З a я оснин и ень Ше "а ; Z и шчи "й в ке яны sнны воно ч s , з у К i й | I Z d. y gy i х I U shchy. and і still SHE shi I t x Z sho y E z I Mt i: z z ! gi ; y g I y I che "a , scha Ki I z sche Shi wife eaah y ia 4