DD294234A5 - FINE-POWDER MAGNESIUM HYDROXIDE AND METHOD FOR THE PRODUCTION THEREOF - Google Patents

Abstract

The invention relates to a finely powdered magnesium hydroxide, which is intended in particular as a flame-retardant filler for plastic compounds, and in which the particles are optionally provided with a thin coating of a surface-active substance and a process for its preparation. According to the invention, the grain size of the magnesium hydroxide measured by laser diffraction is less than 10 mm, the median value of the grain size being greater than 0.8 mm and not more than 3 m; the content of water-soluble ionic impurities in the magnesium hydroxide, namely Ca, Na, K, SO4, Cl, is below the limits (in parts by weight) Ca 1,000 ppm, Na 20 ppm, K 20 ppm, SO 4 1,500 ppm, Cl 1,000 ppm , and the content of the magnesium hydroxide of Mn, Ni and Cu is below the limits (in parts by mass) MnO100 ppm, NiO100 ppm, CuO10 ppm. The process for producing the magnesium hydroxide is based on a magnesium oxide obtained by spray residues from a magnesium chloride solution previously purified of impurities, water is added to hydrolyze, and the resulting magnesium hydroxide is filtered off and the filter cake material is subjected to water washing. Coating; surface active substance; Purity; Korngroesze; Filler; Plastic grain pounds}

Description

-2- 294 234 Field of application of the invention

The invention relates to a finely powdered magnesium hydroxide, which in particular as a flame-retardant filler for Plastic compounds is provided, and wherein the particles optionally with a thin coating of a

surface-active substance are provided and a method for its preparation.

The finely powdered magnesium hydroxide according to the invention is used as a flame-retardant filler for Plastic compounds. Characteristic of the known state of the art

Finely powdered magnesium hydroxide is often used as a flame retardant filler for plastic compounds, in particular for plastic compounds based on thermoplastics. In this case, relatively large amounts of magnesium hydroxide are added to the plastics, the mass of the magnesium hydroxide often being between half and twice the mass of the plastic. There are now feinpulverige Magnesiumhydroxidsorten often properties which exert a negative influence on the mechanical properties of plastic compounds to which such magnesium hydroxide is added as a filler. It is often found on such plastic compounds or on objects that are made of such plastic compounds, eg a tendency to relatively high water absorption, a reduction in the tensile strength and increased aging tendency. It is also often the fluidity and plasticity of such plastic compounds and the appearance of the surface of the articles made of such plastic compounds by the properties of certain finely powdered magnesium hydroxide, z. B. by their grain structure and their content of water, adversely affected. DE-C3-2624065 describes a magnesium hydroxide in which a special structure of the particles is present, which should eliminate disadvantages of the aforementioned type when using this magnesium hydroxide in plastic compounds. The particles are said to have a deformation in the (101) direction of not more than 3 × 10 ^-3 , a crystal size in the (101) direction of more than 800 A and a specific surface area, determined by BET, of less than 2OmVg to have. According to DE-C3-2659933, to eliminate the disadvantages of the aforementioned type, in addition to this structure of the particles of magnesium hydroxide, it is additionally provided that these particles are coated with anionic surface-active substances. However, it has now been found that the aforementioned structural parameters are not suitable for characterizing a magnesium hydroxide to be used for the purpose mentioned above, with which the mentioned disadvantages can be reliably eliminated. In practice, despite the existence of such a structure, the disadvantages mentioned can occur.

Object of the invention

The aim of the present invention is to provide a finely powdered magnesium hydroxide of the type mentioned, which reliably eliminates the aforementioned disadvantages when used as a flame retardant filler in plastic compounds and even after a long time no impairment of the chemical and physical properties, insbosondere the electrical insulation and chemical resistance, and also does not cause any impairment of the mechanical properties and the dimensional stability or disadvantageous changes of the plastic compounds under the influence of moisture and other environmental influences is not favored. The finely powdered magnesium hydroxide to be produced is also intended to enable easy processing of plastic compounds in which it is intended as a flame retardant filler and to achieve good strength properties of the articles made from such plastic compounds as well as a uniform closed surface on these articles which does not interfere with surface defects to let.

Characteristics of the essence of the invention

The invention is based on the object, a very fine magnesium hydroxide with a given grain size and high purity available to sieücn.

The inventive finely powdered magnesium hydroxide of the type mentioned above is characterized in that the grain size of the magnesium hydroxide, measured by laser diffraction, is below 10μπι and here the median grain size greater than 0.8Mm and at most 3 pm, that the content of magnesium hydroxide of water-soluble ionic impurities , Ca ⁺⁺ , Na ⁺ , K ⁺ , SO ₄ ", Cl ^{- is} below the below-mentioned limits (in parts by weight): Ca ⁺⁺ <1000 ppm, Na ⁺ <20 ppm, K ⁺ <20 ppm, SO ₄ ~~ <1600 ppm , CI "<1000 ppm, and that the content of magnesium hydroxide of Mn, Cu and Ni, below the limits (in mass tables) MnO <100 ppm, NiO <100 ppm, CuO <10 ppm.

By this design, the above-mentioned Zielsetzwiderstand and the electrical breakdown strength of bodies or Gegonständen, which consist of a filled with such a magnesium hydroxide plastic compound, are significantly higher than when using other, previously common varieties of magnesium hydroxide, and this is particularly evident occurs when such bodies or objects are exposed to the action of moisture. In addition, the maintenance of said values of water-soluble ionic impurities of the magnesium hydroxide, a swelling occurring under the influence of moisture plastic compounds, which could often be observed when using previously common types of magnesium hydroxide, effectively prevented, and it is with the inventive

Magnesium hydroxide very good mechanical properties (for example, in terms of strength, elongation at break and dimensional stability) of the articles made of the plastic compounds and also a good resistance thereof to aging phenomena achieved. It also contributes to maintaining the values given for heavy metal contamination, which may be explained by the fact that this maintenance virtually eliminates chemically adverse effects on the plastic (eg, oxidative degradation). Also, the observance of the said maximum value of the grain size contributes to the achievement

good mechanical properties and to largely avoid adverse effects of external influences, in particular moisture, in that it can achieve a high surface quality of the body or objects produced from the plastic compounds, ie a dense and closed surface, which counteracts the penetration of foreign substances. Likewise, said grain size is advantageous for achieving good tensile strength. Also, keeping the said median ("d _M ") range of the grain size of the magnesian hydroxide is advantageous for obtaining favorable mechanical properties of the plastic compounds and further seeking the flame retardancy Grain size measurements are based on laser diffraction, and grain size measurements with other measuring methods may give different values

Laser diffraction, an oversize fraction of up to 1% (mass) is not detected. It appears to be a particular advantage that body or articles, which are made of plastic compounds, as Filler contain the magnesium hydroxide according to the invention, various favorable mechanical properties in Show combination with each other. For example, with elastomeric plastic compounds very good values of Tensile strength and good values of the Reißdohnung be achieved. A preferred embodiment of the finely powdered magnesium hydroxide according to the invention provides a particularly good Resistance to moisture, before that the content of Ca ⁺ \ Na ⁺ , K ⁺ , SO ₄ "", Cl ^- below the limits Ca ⁺⁺ <500ppm, Na ⁺ <10ppm, K ⁺ <10ppm, SO, ""<800pprri, cr <BOOppm. With regard to the content of magnesium hydroxide in heavy metals, a preferred embodiment provides that the Content of Mn, Cu and Ni is below the MnO <50 ppm, NiO <50 ppm, CuO <5 ppm. It can be that way

catalytic promotion of degradation phenomena of the plastic are virtually completely eliminated.

It is further advantageous in terms of flame retardancy of the finely powdered magnesium hydroxide, if

provides that the Ulühverlust of magnesium hydroxide is> 30.0%.

The electrical conductivity of the magnesium hydroxide, determined according to DIN 53208 on an aqueous suspension, is advantageous

<500 με / οΓΠ, preferably <300 pS / cm.

It has with regard to the achievement of favorable mechanical properties of the plastic compounds or the thereof

produced items and also with regard to the flame retardant effect of magnesium hydroxide a maximum value of

Grain size of 7 pm and a median grain size of 1 ± 0.2 pm proved to be particularly advantageous. With regard to the processing of the magnesium hydroxide with the plastic to a plastic compound or in terms of Dispergierens of magnesium hydroxide in plastic and also with regard to influencing the Ε-module with Magnesium hydroxide filled plastic compounds, it is advantageous if the "aspect ratio" said ratio of Diameter of the primary particles of magnesium hydroxide to the height of these primary particles is between 2 and 6. A relationship

the diameter of these primary particles to their height, which is between 3 and 4, is particularly favorable for the

Dispersibility. The optional provision of a thin coating of a surfactant on the particles of the Magnesium hydroxide is above all with regard to a further improvement of the dispersibility and another Improvement of the mechanical properties of the plastic compounds of advantage. You can do it with relative

small amounts up to about 2%. based on the mass of magnesium hydroxide, find the Auslangen.

The invention also relates to a process for the preparation of the pulverulent magnesium hydroxide, and this Process is characterized in that by Sprühösten from a previously cleaned of foreign substances Magnesium chloride solution obtained magnesium oxide, in which the content of Ca ⁺⁺ , Na ⁺ , K ⁺ , SO ₄ ^- ", Cl" below the limits (in Parts by weight): Ca ⁺⁺ <10000 ppm, Na ⁺ <10OO ppm, K ⁺ <1000 ppm, SO ₄ ""<3000 ppm, Cl "<100 000 ppm, and in which the Content of Mn, Cu and Ni, below the limits (in parts by weight): MnO <150 ppm, NiO <150 ppm, CuO <15 ppm, with water

is added that the suspension is allowed to react with stirring, that then the resulting in the suspension

Magnesium hydroxide is filtered off and the filter cake material of a once or more Nsnhwäsche with demineralized Water is subjected to that the filter cake material is then re-dehydrated and then dried. For the Hydration of the magnesium oxide is preferably used demineralized water Advantageously, in the process according to the invention, the suspension is submerged at a temperature between 55 ^° C. and 100 ^° C. Stirring allowed to react. With regard to a rapid and complete course of the hydration and with regard to the achievement

of the essential for the inventive magnesium hydroxide characteristics it is advantageous if the suspension is allowed to react at a temperature between 80 and 9O ⁰ C with stirring.

It is possible in the context of erf indungsgemäßon method in a particularly simple manner, the special properties or Characteristics that are present in the inventive finely powdered magnesium hydroxide to achieve, if it is provided that the Magnesium chloride solution of theirs, by digestion of a magnesium silicate material or magnesium hydrosilicate material,

such as olivine, serpentine, Garnierit or the like., Prepared with hydrochloric acid and subsequent purification of pulping slurry.

The extraction of the magnesium oxide takes place in the inventive method by spray roasting a Magnesium chloride solution. In this technique, a magnesium chloride solution is sprayed in a reactor in which a

exists of burners produced hot gas atmosphere. It finds a practically complete pyrohydrolysis of

Magnesium chloride instead, while other components of the magnesium chloride solution, for. B. water-soluble K, N or Ca salts,

not be changed.

It can be mentioned that also deviates from the aforementioned Sprühösten process for the preparation of Magnesium hydroxide and magnesium oxide are widely used. How to win Magnesium hydroxide and magnesium oxide from sea water the sea water with lime milk or dolomitic milk added, where it

precipitation of magnesium hydroxide occurs, which is separated by sedimentation and then washed, after which the resulting magnesium hydroxide can be converted by thermal treatment in magnesium oxide. This production of magnesium hydroxide and magnesium oxide is subject to various adverse influences

Foreign substances that are in the seawater and in the milk of lime or dolomite milk and which are also disadvantageous in the end product

be exposed. Furthermore, the invention relates to the use of the inventive finely powdered magnesium hydroxide flame retardant filler in plastic compounds. A preferred use

of the finely powdered magnesium hydroxide according to the invention is characterized in that the magnesium hydroxide is used as a flame-retardant filler in plastic compounds whose plastic component is a thermoplastic. Finally, the invention relates to a plastic compound containing a plastic and flame retardant filler according to the invention as a magnesium hydroxide. A preferred plastic compound is characterized in that the compound contains a thermoplastic as a plastic component and a magnesium hydroxide according to the invention as a flame-retardant filler.

Au3föhrungsbeispiel The invention will now be further explained with reference to examples: example 1

101 deionized water are placed in a reaction vessel and brought to a temperature of 7O ⁰ C. 850 g of a magnesium oxide having the chemical analysis and particle size analysis shown in Table I, column 1, prepared by pyrohydrolysis of a magnesium chloride solution are introduced into the initially charged solution and sufficiently stirred by means of a stirrer for 3 hours. After the hydrothermal treatment, the product is filtered and washed with water. After drying, a product is obtained whose chemical analysis and particle size analysis are listed in Table II, column 1. The electrical conductivity of the magnesium hydroxide prepared in this way was determined according to DIN 53208 on an aqueous suspension at 265 pS / cm. The primary particles have a diameter / height ratio of 3 to 4.

Example 2

101 demineralized water are placed in a reaction vessel and heated to 85 ° C. 2 kg of a magnesium oxide with the chemical analysis and particle size analysis given in Table I, column 2, which by Pyrohydrolysis a

Magnesium chloride solution is prepared, are stirred into the solution and hydrothermal for 5h Treatment suspended. The product is then filtered at 85 ° C and washed with water. After drying, a product is obtained whose chemical analysis and particle size distribution in Table II, column 2,

is summarized. The electrical conductivity, determined according to DIN 53208 on an aqueous suspension, was 382 pS / cm.

The primary particles showed a diameter / height ratio of 5 to 6. Example 3

1500 g of a magnesium hydroxide prepared according to Example 1 were mixed intensively with 15 g of an alkoxysilane in a high-speed mixer for 15 minutes and surface-modified in this way.

Example 4

There were 100 parts by mass of an elastomeric ethylene-propylene-diene polymer (EPDM), which was in the form of a powder, intimately mixed with 220 parts by weight of a magnesium hydroxide obtained according to Example 1 and were then prepared from this plastic compound by injection molding test specimens and these specimens were tested according to DIN 53670. The results of this study are listed in column A of Table III.

Example 5 The procedure was according to Example 4, wherein the same polymer but obtained according to Example 3 magnesium hydroxide

was used. The results of the investigation of the specimens prepared from the plastic compound are in

Column B of Table III. Comparative Example 1 The procedure was as in the example, but the same polymer was a commercial one Seawater produced magnesium hydroxide was used. The results of the investigation of the Plastic compound produced specimens are listed in column C of Table III. Comparative Example 2 The procedure was as in Example 4, but the same polymer but a surface-modified Magnesium hydroxide, as it is Γη DE-C3-2 659933 described was used. The results of the investigation of

The plastic compound prepared specimens are listed in column D of Table III.

It is immediately apparent from Table III that the test specimens, which are made of plastic compounds, as Filler erfindungägemäßes magnesium hydroxide (columns A and B) high tensile strength and at the same time

show a good value of elongation at break and also a low swelling when stored in water.

For test specimens, which were made of plastic compounds, the filler as a commercial, from seawater

produced magnesium hydroxide (Table III, column C) results in a comparison with the values of columns A and B of Table III significantly lower tensile strength and increased swelling in water storage. The use of another known magnesium hydroxide, which is surface-modified (Comparative Example 2-Table III, column D) leads to a lower swelling, but also greatly reduces the tensile strength.

Example 6

To form a plastic compound, 100 parts by weight of PP 8400 polypropylene were thoroughly mixed with 150 parts by weight of a magnesium hydroxide obtained according to Example 1, and test specimens were then injection molded from this plastic compound, and these specimens were tested for tensile strength and elongation at break according to DIN 53455 , tested for impact strength according to DIN 53453, for burning properties according to ASTM D 2863-77 and for flame retardance according to UL 94 / V (3 mm); Furthermore, according to an internal comparative method, the flow length of the plastic compound during injection molding at 24O ⁰ C was determined as a measure of the processing market. The measured values obtained are listed in Table IV, column A. With regard to the combustion properties, the Limiting Oxygen Index (LOI) value was determined, which corresponds to the minimum oxygen content (% O ₂ ) of the ambient atmosphere required to maintain the burn-up.

UL 94 / V (3 mm) are Underwriters Laboratory guidelines for performing flame retardance tests on specimens of 3mm thickness in a vertical position; chops! indicates V-O .. best result, V-1 .. mean result, H.B ... high burning (burned).

Example 7 The procedure was as in Example 6, wherein the same polypropylene as in Example 6, but one obtained according to Example 3 Magnesium hydroxide, was used. The results of the investigation from the. \ Sm plastic compound through Injection molded specimens are listed in column B of Table IV. Comparative Example 3 The procedure of Example 6 was repeated using the same polypropylene as in Example 6 but with

commercial, produced from sea water magnesium hydroxide, as it had been used in Vargleichsbeispiel 1 was used. The results of the investigation of the made from this plastic compound by injection molding

Test specimens are listed in column C of Table IV. Comparative Example 4 The procedure of Example 6 was repeated using the same polypropylene as used in Example 6, but with

surface-modified magnesium hydroxide as used in Comparative Example 2 was used. The

Results of the investigation of the test specimens produced from this plastic compound by injection molding are in Column D of Table IV. Comparative Example 5: There were used from that in Examples β and 7 and Comparative Examples 3 and 4 Polypropylene prepared without addition of magnesium hydroxide by injection molding test specimens and those in these examples

and Comparative Examples were subjected to investigations. In this case, those listed in column E of Table IV were

Results obtained.

Table I magnesium oxide

%-Dimensions 1 30.5 2 Chemical Analysis %-Dimensions 0,012 MgO (from the difference) %-Dimensions 98.2 0.005 94.1 SiO ₂ %-Dimensions 0.005 0,003 0.02 CaO %-Dimensions 0.50 0,006 12:52 Al ₂ O ₃ %-Dimensions 0,010 99.9 0,002 Fe ₂ O ₃ %-Dimensions 0,007 <0.001 0,004 MnO %-Dimensions 0.0005 <0.001 0,003 NiO %-Dimensions 0,003 0.028 0,002 Na ₂ O %-Dimensions 0.02 0,014 0,018 K ₂ O %-Dimensions 0.02 <5 0,012 SO ₄ - m '/ g 0.04 4 0,065 ci 1.2 20 5.28 spec. Surface BET μηη 5.0 11 4.7 Grain * ANALYSIS: μιη Median value d _M 2.43 1.19 2.68 Upper particle size limit 24.6 6.0 24.6 Table II magnesium hydroxide 1 2 Chemical Analysis %-Dimensions Glühverlustbei1000 ° C / %-Dimensions 2 hours %-Dimensions 30.52 SIO ₂ %-Dimensions 0,021 Fe ₂ O ₃ %-Dimensions 0,002 Al ₂ O ₃ %-Dimensions 0,002 CaO %-Dimensions 0.001 Mg (OH) ₂ (from the difference) %-Dimensions 99.9 Na ₂ O %-Dimensions <0.001 K ₂ O %-Dimensions <0.001 SO ₄ - ppm 0 / H7 cr ppm 0.Ü82 CuO ppm <5 MnO MVG 20 NiO 14 spec. Surface BET μηη 14.5 Grain analysis: μιη Median value d _M 1.41 Upper particle size limit 5.0

Table III Investigations on specimens

Plastic compound Type of A B C D exam Hardness to Shore A DIN 53 505 85 86 81 79.5 Tensile strength / Nmm " ² DIN 53 504 original 7 days 135 ⁰ C " 7.0 10.0 4.4 2.8 28 days water storage 5O ⁰ C ²¹ 10.2 12.8 6.3 2.8 Elongation at break /% 6.6 7.8 4.0 3.1 DIN 53 504 original 7 days135 ⁰ C " 224 185 212 534 28 days storage of water 5O ⁰ C ²¹ 179 ^ 145 178 479 Swelling with water storage /% ²¹ 247 230 422 * 464 1 day 3rd day 0.9 0.4 1.5 0.4 7th day 1.5 0.8 3.8 0.7 14th day 2.0 1.3 8.2 0.9 21st day 2.5 1.7 9.8 1.4 28th day 2.7 1.8 10.5 1.8 vulcanization 2.8 2.0 11.8 1.9 Lowest torque M ₁ Highest torque Mh 10.0 9.8 5.4 2.5 64.1 63.2 57.8 37.3

1 The hot air aging was carried out in accordance with DIN 53608 by storage at 135 ⁰ C for 7 days.

2 The water storage was carried out in accordance with DIN 63521 by exposing the specimens to the contact medium water for a period of 28 days at GO ⁰ C.

Table IV

Plastic compound Type of A B C D e 23.0 exam > 1 Tensile strength (N / mm ² ) 25.0 20.8 18.2 18.0 o. Br. Elongation at break (m / m) 0,035 0.34 0.026 0.22 17.1 Impact strength (KJ / m ² ) 10.0 o. Br. 3.0 o. Br. H. B. LOI {% O ₂ ) 27.0 n.d. n.d. 23.8 UL94 / V (3 mm) V-O V-O V-1 H. B. 15.0 Flow length during injection molding 240 ° C (cm) 13.5 14.0 6.0 15.0

Impact toughness o. Br. = Without break LOI n. B. = not determined

Claims (17)

claims: 1. Pulverulent magnesium hydroxide, which is provided in particular as a flame-retardant filler for plastic compounds, and in which the particles are optionally provided with a thin coating of a surface-active substance, characterized in that the grain size of the magnesium hydroxide, measured by laser diffraction, is below ΙΟμιτι and here the Median value of the grain size greater than 0.8Mm and at most 3μητι is that the content of the magnesium hydroxide to waGserlöslichen ionic impurities, namely Ca ⁺⁺ , Na ⁺ , K ⁺ , SO ₄ ", Cl" below the limits below (in parts by weight) Ca ⁺⁺ <1000 ppm, Na ⁺ <20 ppm, K ⁺ <20 ppm, SO ₄ "<1500 ppm, Cl"<10000 ppm, and that the content of magnesium hydroxide in Mn, Ni and Cu is below the limits (in parts by weight) MnO < 100 ppm, NiO <100 ppm, CuO <10 ppm. 2. feinpulveriges magnesium hydroxide according to claim 1, characterized in that the content of Ca ⁺⁺ , Na ⁺ , K ⁺ , SO ₄ ", Cl" below the limits Ca ⁺⁺ <500 ppm, Na ⁺ <10 ppm, K ⁺ <10 ppm, SO ₄ ""<800 ppm, Cl "<500 ppm. 3. feinpulveriges magnesium hydroxide according to claim 1 or 2, characterized in that the content of Mn, Cu, Ni is below the limits MnO <50 ppm, NiO <50 ppm, CuO <5 ppm. 4. Feinpulveriges magnesium hydroxide according to any one of claims 1 to 3, characterized in that the loss on ignition of the magnesium hydroxide> 30.0%. 5. A fine powdered magnesium hydroxide according to any one of claims 1 to 4, characterized in that the electrical conductivity of the magnesium hydroxide <500uS / cm. 6. feinpulveriges magnesium hydroxide according to claim 5, characterized in that the electrical conductivity of the magnesium hydroxide <300 pS / cm. 7. feinpulveriges magnesium hydroxide according to any one of claims 1 to 6, characterized in that the median value of the grain size at 1 μηη ± 0.2 \ im . 8. feinpulveriges magnesium hydroxide according to any one of claims 1 to 7, characterized in that the grain size of the magnesium hydroxide '.intermediately 7 μηη. 8. Feinpulvariges magnesium hydroxide according to any one of claims 1 to 8, characterized in that the ratio of the diameter of the primary particles to the height between 2 and 6. 10. A fine powdered magnesium hydroxide according to claim 9, characterized in that the ratio of the diameter of the primary particles to their height is between 3 and 4. 11. A process for preparing a finely powdered magnesium hydroxide according to any one of claims to 10, characterized in that by spray roasting from a magnesium chloride previously purified from impurities magnesium oxide solution in which the content of Ca ⁺⁺ , Na ⁺ , K ⁺ , SO ₄ "" , Cl "below the limits (in parts by weight): Ca ⁺⁺ <" 10000ppm, Na ⁺ <10OOppm, K ⁺ <1000ppm, SO ₄ ""<3000ppm, Cl "<" 10000ppm, and the content of Mn, Cu and Ni, below the limits (in parts by weight): MnO <150 ppm, NiO <150 ppm, CuO <15ppm is added, water is added, that the suspension is allowed to react with stirring, that is then filtered off in the suspension resulting magnesium hydroxide and the filter cake material of a one or more after washing with demineralized water is subjected, that the filter cake material then drained again and then dried. 12. The method according to claim 11, characterized in that the hydration of the magnesium oxide deionized water is used. 13. The method according to claim 11 or 12, characterized in that the suspension is allowed to react at a temperature between 55 ° C and 100 ⁰ C with stirring. 14. The method according to claim 13, characterized in that the suspension is allowed to react at a temperature between OO and 9O ⁰ C with stirring. 15. The method according to any one of claims 11 to 14, characterized in that the magnesium chloride solution in turn by digestion of a magnesium silicate or magnesium hydrosilicate material, such as olivine, serpentine, Garnierit or the like., Is prepared with hydrochloric acid and subsequent purification of the pulping slurry. 16. Use of a finely powdered magnesium hydroxide according to one or more of claims 1 to 10 and 11 to 15, characterized in that the magnesium hydroxide is used as a flame-retardant filler in plastic compounds. 17. Use of a finely powdered magnesium hydroxide according to claim 16, characterized in that the magnesium hydroxide is used as a flame-retardant filler in plastic compounds whose plastic component is a thermoplastic.