DE2146164C3 - Synthetic resin composition made of thermoplastic resin - Google Patents

Description

3 4

Silicon dioxide, asbestos, cement, earth and sand, glass forming a foam is a compounding fiber, metal salts and metal oxides, used in a ratio of up to 900/100 permissible,
will

^ Since the mass of the invention is accessible to the 2. Melt casting method

™, gluing with metals, paper, fibers, asbestos, concrete, 5 According to this method it is possible to measure the mass of

ί, plaster of paris and clay, it is for the production of with invention from 100 parts by weight of the thermoplastic

t composite bodies connected to these materials seen resin and up to 300 parts by weight of the

.- suitable. The connection can be effected by forming brandes, with a mass of 20 to

adding the materials to the molded article 200 parts by weight per 100 parts by weight of the resin

ι lets stick out of the mass or, alternatively, by * <> due to the superior properties of the molded

»That a mixture of the mass and the object is preferred at the same time. Although a crowd with

the material to form a solidified counterpart with a compounding ratio of less than

Stand deformed. 20/100 can be formed, it is due to its shape

The composition of the invention results in a molded ring specific gravity insufficient to achieve that

To achieve the object not only according to a general form-15 characteristic of the invention. To the-

\ method, such as extrusion, injection, blowing, compressing is a mass with a ratio of

'.sion or rotational molding, but also after a more than 300/100 in terms of their use

'' A special method suitable for these masses, due to the low compressive strength of the

Melt casting, which will be explained below. shaped object limited. With this method The mass and the molded article therefrom 20 can be the resin either in the form of fresh granules

can be prepared according to the invention as follows: (granules) or powders or in the form of used ones

shaped objects or in the form of scrap

, 1. Mixing and molding method can be used. Use in the latter

The thermoplastic resin and the burn-off will form the characteristic of this method mixed and kneaded according to a general method rather than the former.

* method using a mixing roller, a The shape of the object to be molded is not

Banbury mixer or extruder and into a web, delimited by some specific shapes, and granules, flakes or blocks of the mass are formed building blocks, rods and rods, pipes etc., which the raw material for manufacture is formed by casting can be shaped, represent various shaped objects. If 30 is preferably produced by this method,
a Banbury mixer or extruder is used, the method is by mixing and heating

the burn should preferably be dried, and carried out while a mixture of the thermoein Ventilation type extruder is preferred. plastic resin and the burning in a melting

According to this method, 100 parts by weight of the crucible at a temperature above the melting point : thermoplastic resin and 5 to 1200, preferably 35 of the resin is stirred by pouring the molten

wise 20 to 1000 parts by weight of the burned-off mixture in a mold or sand mold. If the amount of burnup is less than a desired configuration and by cooling: 5 parts by weight, the effect of the invention cannot be obtained for obtaining the relevant shaped counterpart, and in cases where the amount of booth. The dimensional accuracy of this method of burn-off is more than 1200 parts by weight, is somewhat worse than that of conventional methods, but the mass obtained can hardly be shaped and in practice the objects cannot be used advantageously for building mathematics. Furthermore, in the case of rials, underwater rams for fishing and industrial molding of the mass, the compounding ratio of materials is used,
The invention is illustrated in detail by way of examples

dependence on the molding methods and the 45 explained in more detail, which the scope of the invention turns of the molded body. When the crowd doesn't limit one.
Extrusion molding is subjected to into a. -I ₁

Web to be deformed, the mass is made by Example 1

Compounding the burn-up with the resin or pyrite burn-up and polyethylene (melt index

by diluting a basic or sample batch 50 = 1.5 g / 10 min., density = 0.923 g / cm ³ ) were prepared with the resin in such a way that it is mixed and kneaded with a mixing roller, so that the compounding ratio, Based on weight, specific gravity of the resulting composition became 1.1, amounts to 5 to 100/100. The resulting composition was subjected to the compression-appropriate compounding ratio molding to form a web.
Mass becomes a counterpart to extrusion molding. Masses with a specific structure, such as pipes or rods or rods with a weight of 1.1 made of iron oxide, lead peroxide, zinc powder, have an irregular cross-section. Iron powder or zinc white instead of pyrite burn-off

§F When the mass of an injection molding is made and by the same method to one

fe is thrown, the compounding ratio web is to be processed.

jf 5 to 300/100 parts by weight, and that by 60 The resistance to breakage of the resulting sheets If the same method as described above was used under environmental stress after the test Asked mass is using a general method according to ASTM D 1693-60T in a Testjj Injection molding device shaped. This mass becomes a solution containing 30 percent by weight of nonylphen-S supplied to blow molding. In the case of compression oxypolyethanol as a surface-active agent, beil the compounding ratio up to 65 is correct.

jj 1000/100, and the mass can be obtained by mixing. The results of the test are shown in Table IV.

fc and kneading of the resin and the burnup, which shows that the mass of the invention using a mixing roller. In which each of the comparison masses is superior.

Table IV

filler

Amount of filler used% by weight Time required
until the break of
50% of the samples
H

Time required
until break
of all samples

Burn-off 20th 2.03 4.67 Iron oxide 20th 1.00 2.17 Lead peroxide 18th 1.00 2.08 Zinc powder 19th 1.33 3.00 Iron powder 18th 0.97 2.50 Zinc white 19th 0.50 1.08 nothing - 0.49 1.28

It can be seen that, compared to iron oxide alone, pyrite burn-off gives a significant effect in spite of the fact that its main component - 'is iron oxide. The characteristic of burn-off is believed to be a combination of iron oxide, the other metal and non-metal oxides and sulfur according to Table I.

Example 2

A mass was produced by the same methods as in Example 1, with the exception that the polyethylene used had a melt index = 7 g / 10 min. And a density of 0.920 g / cm ³ . The mass was subjected to compression molding under the condition of 175 ° C for 15 minutes to form brick sheets and roof tiles.

The physical properties of the molded article are shown in Table V.

Table V

Amount of

used

Burn-off

Weight percent A

Surface Shore hardness

Abrasion specific loss *) sches

Weight

mg

35

40

*) The abrasion loss was measured under a load of 1000 g and the rotation of an abrasion ring (CS-17) of 1000 determined by the Taber abrasion tester.

The weatherability of the molded article is shown in Table VI, which shows the strength

Table VII

80 100 71 283 2.65 85 100 72 298 3.00 90 100 83 305 3.40

represents is in units of tensile strength after specimens are irradiated in a weatherometer became.

Table VI

Amount of Before the at Tensile strength (kg / cm ^s ) 4O0h 600 h 800 h used Irradiation after 112 116 114 Burn-off 106 111 110 Weight 110 109 111 percent 200 h I 3 5 120 117 17th 112 102 23 114 104 game

A sample batch consisting of polyethylene (melt index = 7 g / 10 min., Density = 0.920 g / cm ³ ) and pyrite burn was diluted with the same polyethylene to obtain a compound with a compounding ratio of burn to polyethylene of 25/100.

Another mass was produced by the same procedure as above with the proviso that that ethylene-vinyl acetate copolymer (content of vinyl acetate unit = 10 percent by weight, melt index = 1.5) was used instead of polyethylene.

The masses were extruded through an extruder into a sheet with a thickness of 0.35 mm. the physical properties of the webs were determined and the results are shown in Table VII.

It can be seen that the polymer incorporated with pyrite burn-up has a high-frequency welding property has been improved considerably.

sample EVA *) EVA E *) E. D 2021 D 2021 L 705 L 705 Amount of burn-up used 20th 20th (Weight percent) Tensile strength (kg / cm ² ) 160/150 115/80 150/140 110/80 Strain (%) 470/550 325/355 450/500 330/350 Tensile strength (kg / cm) 47/60 47/81 40/50 40/50 Impact strength (kg-cm) 25th 20th 15th 14th Heat seal strength 6.6 5.6 5.0 4.7 (kg / 15 mm width) High frequency seal strength 0 4.7 0 6.0 (kg / 15 mm width) Moisture permeability (g / m ² · 24 h) 2.1 2.5 1.8 2.1

*) EVA - ethylene vinyl acetate copolymer, E = polyethylene.

D e i sp i c 1 4

A mass was produced by kneading a mixture of 60 parts by weight of pyrite burned off and 40 parts by weight of polyethylene (melt index = 20 ^ / 10 min .; density = 0.919 g / cm ³ ) by means of a mixing roller. Tiles, construction goats, and other molded articles were formed by subjecting the mass to injection molding using a snail-type injection device under the following conditions.

C ₁

C ₃

Mold temperature ( ⁰ C) 180 200 210 210

Injection pressure (kg / cm ² ) 800

Injection speed 50

(mm / min.)

Injection time (sec.) 10

Cooling time (sec.) 50

Mold temperature ( ⁰ C) 40

The resulting molded articles have a good appearance. With regard to impact resistance, neither occurs a breaking or tearing or bursting of the roof tiles, even if they were ten times from a height of 3 m can be dropped. The roof tiles have such good weather resistance properties that the tiles no change after 100 hours of irradiation in a watering device with two carbon sheets (obtained from Shimazu Manufacturing Co.) show. The good flame retardancy of the roof tiles is evident in the fact that the bricks do not burn, but they become dark on their surface, when exposed to a town gas flame at a distance of 3 cm for 5 minutes.

Example 5

There was prepared a paste by mixing the following materials were mixed in the amounts listed below for 10 minutes by a mixing roll at a temperature of 12O ⁰ C and kneaded.

Parts by weight

Ethylene-vinyl acetate copolymer
(Content of vinyl acetate unit = 15 percent by weight, melt index = 1.5 g /

10 min.) 100

Pyrite burn 25

Crosslinking agent 3

Foaming agent 5

Zinc stearate (excipient) 3

A foamed body was produced by placing the mass in a mold with a dimension of 200 × 200 × 10 mm and subjecting the mass to foaming under a pressure of 100 kg / cm ² at a temperature of 175 ° C. for 15 minutes .

The resulting foam is good in appearance and has a bulk density of 0.27 g / cm ³ , a hardness (ASKER type C) of 58, a rectangular tear strength of 20 kg / cm ² , a tensile strength of 25 kg / cm ² , an elongation at break of 200% and a compression reduction at 40 ^° C. of 65%.

In further experiments it was observed that the resulting foam became soft and rubbery.

Examples

There has been a. Mass produced; by burning 100 [parts by weight of polypropylene, and 140 parts by weight of pyrite burning in a Banbury mixer, *. which would be kept at 190 ^° C., mixed and kneaded. A sheet would be made from the mass. · Under

ίο Using the web as Kerri material, a layered plank or plate was produced by placing the web between two webs of pure aluminum sheet with a thickness of 0.5 mm, which were degreased with trichlorethylene, and the composite under a pressure of 50 kg / cm ² was compressed at a temperature of 200 ⁰ C for 10 minutes by means of a compression device of the compressed composite was provided with a measuring device for determining the strength.

For comparison, a layered plate with a core was made using the same procedures the specified pure polypropylene web instead of the web made of the mass and with an additional adhesive film a thickness of 50 μ made of ethylene vinyl acetate

Mixed polymers! (EVA) or made of ethylene glycidyl methacrylate (EGM) between the sheet of mass and each of the aluminum panels.

The bond strength between the two different materials is determined according to ASTM D 906-49 a pulling speed of 5 mm / min. The tensile strengths when peeling off the layered Plates are listed in Table VIII.

Table VIII

Laminate Tensile strength when peeling Propylene and aluminum 0 kg / cm ² Mass and aluminum 5 kg / cm ² Bulk, EVA and aluminum 7 kg / cm ² Ground, EGM and aluminum 10 kg / cm ²

The layered board of the invention can be used as a hardly flammable building material and is, as shown in Table VIII, better in terms of accessibility for adhering to a metal than the layered sheet made of polypropylene.

Example 7

This example illustrates a cylindrical block, made from a molded article made of resins.

A number of mixtures were prepared inden the pyrite burn in amounts of 20, 30, 50, 60 and 70 percent by weight, based on the resulting mixture, with polyethylene blown film (thickness: 0.05 mm, fold diameter 210 mm), and for 6 months afterwards had been aged during manufacture, was mixed. The mixture was brought mn in a zylin-cylindrical crucible made of iron having a diameter of 120 mm through and a height of 300, and the film was melted by di <gehaltei temperature of the contents at 250 to 360 ⁰ C. The contents of the crucible were stirred into a cylindrical shape with a through

1 46 4 64

knives of 52 mm and a height of 150 mm cast and obtained a cylindrical block chilled.

Two rows of cylindrical blocks were made by the same procedure as described above, made using polypropylene film as resin (thickness: 0.07mm, folding diameter: 210 mm), and the 4 months after

10

was aged during manufacture or using bottles made of high-impact polystyrene as resin.

The physical properties of the resulting blocks are shown in Table IX, which further includes those Properties of concrete made from Portland cement after curing for 20 days are also listed for comparison purposes.

Table IX

Samples and amount of added charring weight percent

other Specific Compression Hardness after Weight strength*) Rockwell g / cm ^s kg L. 0.81 2150 47 30th 1.08 1990 48 50 1.37 2110 48 60 1.62 2080 51 70 1.98 1200 - 0.75 1820 60 30th 1.08 2000 63 50 1.46 1850 58 60 1.67 1700 55 70 1.96 600 0.94 3900 82 20th 1.08 4000 80 30th 1.25 4080 78 50 1.54 4360 76 60 1.78 3800 76 3.75 1600 - 50 3.73 1580 -

Polyethylene film alone Polyethylene film + burnout Polyethylene film + burnout Polyethylene film + burnout Polyethylene film + burnout Polypropylene film alone Polypropylene film + burnout Polypropylene film + burned polypropylene film + burned polypropylene film + burned off Polystyrene bottles only Polystyrene bottles + burned polystyrene bottles + burned off Polystyrene bottles + burned polystyrene bottles + burned concrete from Portland cement alone Portland cement + sand 50 concrete

*) Load when breaking a cylindrical specimen with a diameter of 50 mm and a height of 100 mm, tested according to JIS A 1108-1963 using the Shimazu All performance tester.

The stability of the blocks against mineral acid, alkali and salt water is in units of weight gain (Weight percent) shown in Table X after 30 days of immersion at room temperature.

Table X

10% HCl

30% H ₈ SO ₄ 10% NaOH 10% NaCl

Polyethylene + burned off 50 percent by weight Polypropylene + burned off 50 percent by weight Polystyrene + burned off 50 percent by weight

Example 8

Two rows of pipes, containing pyrite burnup in different amounts, were passed through the same Procedures prepared as in Example 7, with the proviso that the resins used are polypropylene and polystyrene, and the amounts of the burn-up mixed were 40 and 30 percent by weight

+0.05 +0.07 +0.04 +0.02 +0.03 +0.05 + 0.02 +0.02 +0.05 +0.05 +0.02 +0.02

and that the shape used has an outer diameter of 150 mm, an inner diameter of 100 mm and a length of 90 mm.

The compression strength of the resulting pipes was measured by the method specified in JIS A 5302-1961. The results are along with those of concrete pipes after one month of curing shown for comparison in Table XI.

Table XI

sample Outer Inner length Com diameter diameter pressure strength mm mm mm kg

Polypropylene + burned 40 percent by weight

Polystyrene + burn-up 30 percent by weight

Portland cement concrete after one month of hardening

150 108 90 500 150 100 90 290 155 107 90 100

Example 9

The block containing 30 percent by weight burn-off, produced according to Example 7, was converted into ballast-like Aggregates for crushed concrete. A cylinder made of concrete with a diameter of 42 mm and one Height of 150 mm was made according to a general method using a mixture equal amounts of weight of the aggregate and cement.

The compression strength of the cylinder was determined according to JIS A 1108-1963 along with that one Concrete cylinder, containing ballast and measured with the same dimension for comparison. The results are shown in Table XII and demonstrate that the mass can be used as an aggregate for concrete can.

Table XII

Concrete cylinder

Compression strength *)

Containing the mass
Containing ballast

1720
1530

Example 10

A series of blocks, containing pyrite burn-up, were made by the same procedures as in the example 7, with the proviso that the resins used are polyvinyl chloride (content of dioctyl phthalate = 30 percent by weight), polyvinylidene film, ABS, polyamide film (30 μ thickness), polyester film (30 μ Starch), and the amount of burn-up mixed in was 60% by weight.

The physical properties of the resulting blocks are shown in Table XIII.

Table XIII

Samples Enamel Specific Compress

temperature weight sion

strength*)

⁰ C g / cm 'kg

*) The compression strength is based on the Shimazu All performance test device measured at a compression speed of 3 mm / min.

Polyvinyl 170 to 250 1.73 1500 chloride Polyvinyli 120 to 200 1.75 1300 denchloride SECTION 220 to 300 1.70 1850 polyamide 270 to 350 1.68 4050 polyester 270 to 360 1.69 3900

·) The compression strength was determined according to JIS A 1108-1963 measured by the same procedure as in Example 7

Claims (1)

1 2 Obtained from pyrite in the form of fine powders, entPatent claim: containing an iron oxide as the main component. Typical Composition, specific weight and particle-thermoplastic molding compounds with iron oxide size distribution of the pyrite burn-up are shown in fol-containing additives, consisting of 5 low tables I, II and III.
100 parts by weight of a polyolefin and 5 to
1200 parts by weight of a Fyritabbrandes as well as Table I.
optionally filler or pigment. composition Weight percent ίο SiO ₂ 7.2 Al ₂ O ₃ 1.5 The invention relates to a synthetic resin compound CaO 0.9 made of thermoplastic resin with iron oxide containing Fe ₂ O ₃ 88.5 tend aggregates. MgO 1.2 It is known to improve the properties 15 S, 0.2 of plastics, especially thermoplastics, a total of 100 to mix in these melal oxides, the content of iron oxide more than 5 %, especially 15 to 40%, Table II of the total weight of the finished mixture. Specific weight 5.2. However, by such admixtures, the chip 20 Tensile fracture resistance of thermoplastics practically- Table III table cannot be improved, so that such a modified particle size distribution of the dried burned-off adorned thermoplastics for applications where. Stress Rupture Resistance is important, weight percent practically out of the question. 25th The object of the invention is to produce synthetic resin compositions from 0 on a sieve of 12 meshes thermoplastic resin to provide the o, 314 on a sieve of 20 mesh excellent stress-rupture resistance on 1.387 on a sieve of 48 mesh point and therefore for the preparation of various 3.475 _au f _e i _ne m sieve of 80 mesh Shaped bodies suitable for which a high tension 30 1.460 on a sieve of 100 mesh Resistance to breakage is essential. 8J45 _au f _e i _nem sieve of 150 mesh The synthetic resin composition of thermoplastic resin 40,500 on a sieve of 200 mesh according to the invention is through a content of 44,719 through 200 meshes 100 parts by weight of a thermoplastic polyol - total:
fins, consisting of z. B. polyethylene, polypropylene, 35 100.00
Ethylene-vinyl acetate copolymer and / or polystyrene, and 5 to 1200 parts by weight of a pyrite burn.The mesh size shows the sieve size, defined and, if applicable, filler or pigment, identified by Tyler standard sieve (Tyler Co. in USA),
draws. The burn occurs as it is generally reddish The synthetic resin compositions according to the invention have a brown color, a reddish brown polymer composition can be characterized by a particularly high tension and correspondingly shaped objects, while resistance to breakage, heat resistance, non-appearance of various coloring due to compounding, flammability, antistatic property and also a suitable amount carbon black or pigments due to a particularly high specific weight. can hereby be obtained.
As a result, the compositions according to the invention are suitable as thermoplastic raw materials suitable for the production of moldings, particularly resin, especially for moldings in the construction industry, including polyolefins, such as the ethylene poly industry, including the woodworking industry. mers or copolymers, e.g. B. Ethylene-vinyl acetate industry. Interpolymer and propylene copolymers or The compositions according to the invention generally have 50 mixed polymers; Polyvinyl or polyvinylidene resins, mean a specific gravity of over 1. Made from such as polystyrene, polyvinyl chloride and polyvinylidene Can chloride building blocks, panels, bricks, roofing tiles; Acrylic resins, including copolymers, or make roof tiles, containers and industrial pipes such as ABS resin; Polyamide resins, polyester resins and others. be asked. The masses are easy to process and the thermoplastic resins can be used after the event can also be glued to other fabrics. 55 discovery not only as fresh resin in the form of The large specific weight of the masses from spheres (pellets) or powders, but also from The article manufactured according to the invention has to be used in the form of so-called scrap furthermore the advantage that they are in contrast to conventional already shaped objects, including Schäu plastics do not swim on water, such as films, boards, sticks, containers and , ^ that waste materials which 60 blocks or debris therefrom '' according to the invention obtained in the processing of the masses as a function, in the sea sunk by the deformation methods and the use may be _f. In this respect, the masses of the earth offer objects to be formed. If such an · Finding not the problems of pollution, the shot can be used already formed _f 'as usual plastics. Another advantage is that the object contains a certain amount of water or the masses according to the invention from cheap raw 65 contain impurity. and waste products can be produced. The burn-up acts as a kind of filler that can be used ,. The slag or the burn-up, which according to the alone or together with other inorganic Invention are used in the calcination fillers, such as calcium carbonate, carbon black, talc, clay,