WO2012048985A1 - Encapsulated iron oxide particles - Google Patents

Abstract

The invention relates to encapsulated iron oxide particles having a needle shape, and comprising a core containing magnemite and magnetite, and a shell containing a metal oxide or metalloid oxide. Said particles are produced in that an aerosol comprising needle-shaped FeOOH particles and optionally shell material particles is brought to reaction in a high temperature zone in a reducing gas atmosphere, and subsequently the material mixture obtained is brought into contact with a quantity of gas comprising oxygen sufficient for completely oxidizing the material mixture, and optionally a plurality of shell material outlet compounds are added, the material mixture is subsequently cooled, and the solids are separated out. The encapsulated iron oxide particles comprise silicone rubber.

Description

 Enveloped iron oxide particles

The invention relates to iron oxide particles coated with a metal oxide, their preparation and use. The invention further relates to a silicone rubber containing these particles.

The inductive heating of composites containing magnetic particles is a promising way for a rapid and gentle curing of adhesive bonds or for the crosslinking of polymers. It has proven to be advantageous to use coated magnetic particles. The shell is attributed the function, on the one hand to improve the incorporation into the networks and on the other to prevent unwanted growth of the magnetic phases.

In principle, such particles can be solvent-based

Systems, such as sol-gel routes or precipitation reactions, as obtained by gas-phase reactions. In WO 2010/063557 silica-coated iron oxide particles are disclosed, which are ideal for inductive heating.

For special applications, however, it has been found that faster heating rates would be desirable. It was therefore the technical task to provide particles with which advantageous properties of in

WO 2010/063557 can be maintained and at the same time significantly increase the heating rate in inductive heating over the prior art. The invention is partially or completely enveloped

Iron oxide particles which are needle-shaped, comprising a maghemite and magnetite-comprising core and a shell comprising a metal oxide or metalloid oxide.

The detection of the iron oxide modifications maghemite and magnetite, as well as hematite can preferably be carried out by means of X-ray structure analysis. The coated iron oxide particles preferably have a length of 0.2 to 5.0 μm and a width of 0.1 to 3 μm, with a length / width ratio of 2: 1 to 20: 1. The particles according to the invention have little or no porosity and the BET surface area is generally 1 to 50 m ² / g, preferably 5 to 20 m ² / g.

The shell material is firmly and irreversibly connected to the iron oxide. It may be present in the form of isolated and / or aggregated, largely spherical particles on the needle-shaped FeOOH particles (schematically in FIG. 1A). It is also possible that the isolated and / or aggregated, largely spherical particles are surrounded by a matrix of the enveloping material (schematically in FIG. 1B). Under matrix is a

To understand largely uniformly distributed amount of the shell material on the needle-shaped FeOOH particles, said shell material shows no discrete particles in a TEM (TEM = transmission electron microscopy) recording. Finally, it is also possible that the matrix represents the sole envelope (schematically Figure 1 C).

The average diameter of the largely spherical particles may preferably be 2 to 50 nm. The thickness of the shell may be 2 to 100 nm, with a thickness of 5 to 50 nm being particularly preferred. As shell material, for example, silica, alumina,

Cerium oxide, titanium oxide or zirconium oxide in question. Furthermore, the shell material may comprise a mixed oxide, for example silicon-aluminum mixed oxide. In a preferred embodiment, the shell material comprises or consists of silica, alumina, ceria, titania or zirconia.

Particularly preferred is silica.

The core of the particles according to the invention comprises maghemite and magnetite. The proportions of these components can be variably adjusted. Thus, the particles according to the invention can have a maghemite / magnetite ratio of 99: 1 to 1:99, preferably 50:50 to 20:80. In addition, the core may also contain hematite. This proportion can be up to 60%, based on the sum of magnetite, maghemite and hematite, all calculated as Fe ₂ 03. In general, the proportion is 5 to 40%. In a particular embodiment, the means

 X-ray iffractometry determined proportion of magnetite 20 to 80%, at

Maghemite 10 to 50% and hematite 3 to 20%, each based on Fe ₂ 03, wherein the proportions add up to 100%.

In some cases, the particles according to the invention may contain up to 2% by weight, but generally less than 1% by weight of alpha-iron.

The coated iron oxide particles according to the invention should have at least a proportion of iron oxide, calculated as Fe ₂ O ₃ , of more than 50% by weight. The proportion of iron oxide is preferably 60 to 95% by weight and more preferably 80 to 90% by weight. The data are to be understood so that the difference to 100 wt .-% corresponds to the proportion of Hüllstoffes.

It may be desired depending on the later use of the particles with the least possible amount of chloride. As a rule, the particles according to the invention have not more than 1% by weight, preferably not more than 500 ppm, of chloride. Lower chloride values are achieved, for example, when low-chlorine or chlorine-free starting compounds are used in the preparation. In these cases, the content of chloride is usually less than 100 ppm.

It has proved to be advantageous if the particles according to the invention have a largely or completely closed shell. As a measure of this, a method can be used, in which one at

Room temperature brings 0.33 g of the particles in contact with 20 ml of 1N hydrochloric acid solution for 15 minutes and the hydrochloric acid subsequently less than 50 ppm, preferably less than 30 ppm, more preferably less than 10 ppm of iron. Part of the solution is then used by means of appropriate Analysis techniques, such as ICP (inductively coupled plasma

spectroscopy).

Another object of the invention is a process for the preparation of the coated iron oxide particles in which

a) in a high temperature zone, preferably at temperatures of

 at least 550 ° C, preferably 550 to 1200 ° C, a needle-shaped FeOOH particles and optionally containing Hüllstoffpartikel containing aerosol in a reducing gas atmosphere, preferably hydrogen or Formiergas, brings, and subsequently the resulting mixture with an amount of an oxygen-containing gas, preferably air , which is sufficient to completely oxidize the substance mixture and

b) optionally followed at one or more locations outside the high temperature zone, wherein the temperature is preferably 300 to 800 ° C, more preferably 550 ° C to 750 ° C and most preferably 600 to 700 ° C, one or more Hüllstoff- output compounds added are,

c) where:

 the filler particles in the aerosol according to a) and / or

Hüllstoff starting compounds according to b) are used, wherein the sum of the Hüllstoffpartikel and the Hüllstoff- starting compounds, calculated as metal oxide or metalloid oxide, the amount of metal oxide or metalloid oxide, as present in the later coated iron oxide particles, wherein the iron oxide content calculated as Fe ₂ 03 is

d) subsequently cools the mixture of substances and separates the solid.

Usually, the oxygen-containing gas mentioned under a) is used in the

Excess used. It has proved to be advantageous if the ratio of oxygen-containing gas used to stoichiometrically required for the complete reaction gas 1, 01 to 5 and especially preferably 1.05 to 1.25. The present after this reaction, water-containing mixture can be further reacted in a subsequent step with a Hüllstoff- starting compound.

The feature c), which states that the filler particles are used in the aerosol and / or shell-starting compounds, is to be understood as meaning that the later silicon dioxide content in the particles according to the invention is

a) the present in the aerosol Hüllstoffpartikeln or

b) the shell-starting compounds or

c) a combination of a) and b)

arises.

 From the mentioned possibilities result various types

Particles according to the invention as shown in FIG. Accordingly, the variant a) provides particles with the structure A,

the variant b) particles with the structure C and

the variant c) particles with the structure B.

 The high temperature zone may, for example, take the form of an external

Heating be provided. In a particular embodiment of the method according to the invention, high-temperature zone represents a flame which is formed by igniting a mixture of a hydrogen-containing fuel gas, preferably hydrogen, and an oxygen-containing gas, preferably air, in a reaction space spatially separate from the aerosol. In this case, the ratio of oxygen in the oxygen-containing gas used to the oxygen required for the conversion of the hydrogen-containing fuel gas, in mol / mol, preferably at least

1, 01, more preferably 1, 01 to 5, and most preferably 1, 05 to 1, 25 be. FIG. 2A schematically shows an arrangement in which the high-temperature zone is formed by a flame which is formed by igniting a mixture of a hydrogen-containing fuel gas and an oxygen-containing gas in a reaction space spatially separated from the aerosol. The following applies: A: needle-shaped FeOOH particles, optionally shell particles, and

 carrier gas

B: reducing gas

 C: hydrogen-containing fuel gas and oxygen-containing gas

D: envelope output connection

E: cooling (air and / or water) and subsequent separation

The mean residence time in the high-temperature zone is preferably 0.5 seconds to 1 minute, preferably 5 to 20 seconds. It is marked with ti in FIG. 2A. It refers to the zone in which the aerosol is reacted in the reducing gas atmosphere. The invention also provides a further process for the preparation of particles according to the invention, in which

a) a mixture of substances comprising a needle-shaped FeOOH particles and optionally aerosol containing Hüllstoffpartikel, a

 oxygen-containing gas, preferably air, and excess hydrogen-containing fuel gas, preferably hydrogen, by ignition, preferably at temperatures of 700 ° C to 800 ° C to the reaction brings b) the substance mixture below further oxygen-containing gas in excess feeds, and allowed to react in a flame .

c) optionally followed by the mixture of substances obtained at one or more points where the temperature is preferably 300 to

800 ° C, more preferably 550 ° C to 750 ° C and most preferably 600 to 700 ° C is added to one or more Hüllstoff- output compounds, wherein applies

the filler particles in the aerosol according to a) and / or Hüllstoff starting compounds according to c) are used, wherein the sum of the Hüllstoffpartikel and the Hüllstoff- starting compounds, calculated as metal oxide or metalloid oxide, the amount of metal oxide or metalloid oxide, as present in the later coated iron oxide particles, wherein the iron oxide content as Fe ₂ 03 is calculated,

d) subsequently cools the mixture of substances and separates the solid.

Figure 2B shows an arrangement in which the aerosol is reacted in the presence of a flame formed by reacting a hydrogen-containing fuel gas with an oxygen-containing gas. Where:

 A: needle-shaped FeOOH particles, optionally hüllstoffpartikel, and

 carrier gas

 B: hydrogen-containing fuel gas and oxygen-containing gas

C: oxygen-containing gas

D: envelope output connection

 E: cooling (air and / or water) and subsequent separation of solids (filter)

Excess hydrogen-containing fuel gas is to be understood as meaning that the ratio of hydrogen-containing fuel gas to the sum of oxygen in the oxygen-containing gas and FeOOH particles, in mol / mol, is greater than 1, preferably from 1:01 to 10 and particularly preferably from 2 to 5 ,

An excess of oxygen-containing gas is to be understood as meaning that the ratio of oxygen in the oxygen-containing gas used to the conversion of the hydrogen-containing fuel gas and the resulting from the reducing treatment iron compounds

required oxygen, in mol / mol, at least 1, 01 to 5, preferably 1, 05 to 1, 25. The mean residence time of the substance mixture, which comprises the acicular FeOOH particles and possibly the filler particles containing aerosol, the oxygen-containing gas and excess hydrogen-containing fuel gas may be 0.5 seconds to 1 minute, preferably 5 to 20 seconds. It is marked with ti in FIG. 2B.

The mean residence time of the substance mixture, which can be reacted in the flame, can be 0.5 to 30 seconds, preferably 1 to 10 seconds, in both processes according to the invention. It is marked with t _{2 in} FIGS. 2A and 2B. The calculation of t ₂ should be based on the ignition of the flame until the supply of water and / or air for cooling.

The aerosol used in the method according to the invention is

expediently by spraying a dispersion containing needle-shaped FeOOH particles and optionally Hüllstoffpartikel, and generates an inert carrier gas. The dispersion is usually an aqueous dispersion having a content of FeOOH particles of preferably 5 to 25 wt .-%. The dispersion may contain dispersing additives, typically in a concentration of 0.05 to 2.00% by weight, based on the dispersion, such as polyacrylic acid and salts thereof. In the event that the dispersion contains silica particles, it has proven useful to use commercially available dispersions of colloidal silica with a content of 5 to 25 wt .-% and a particle diameter of 2 to 50 nm, preferably 10 to 30 nm. Dispersions in the alkaline range, in particular with pH values of 8 to 11, are preferably used in this case.

The needle-shaped FeOOH particles used may be doped with at least one element selected from the group consisting of P, Si, Al, Mg, Co, K and Cr. Such dopants are usually added in small amounts in the course of the synthesis of the oxides to

To control particle size and particle shape. The filler particles used in the process according to the invention are metal oxides or metalloid oxides. This may be preferred

Be silica particles, alumina particles or cerium oxide particles.

Particularly preferred are silica particles. These may be colloidal or pyrogenic silica particles. In general, the primary particle diameter is 5 to 50 nm, preferably 10 to 30 nm.

Hüllstoff-Ausgangsverbindungen are those which are among the

Reaction conditions are converted into metal oxide or metalloid oxide. They can be used as such in the form of a liquid, in the form of a solution or in the form of steam. With particular preference, they are used in the vapor state. The dosage can be done for example by means of a nozzle. The Hüllstoff- starting compounds may be organic or inorganic nature. For example, it is possible to use C 1 -C ₄ -metal alkoxides, such as Si (OC _n H _2n + i) 4 or Al (OCnH ₂ n + i) 3, where n = 1 -4 or metal carboxylates, such as metal octoates.

Also suitable as shell-starting compounds SiCl ₄ , H ₃ SiCl, H ₂ SiCl ₂ , HSCl 3, CH ₃ SCl ₃ , (CH ₃ ) ₂ SiCl ₂ , (CH ₃ ) ₃ SiCl and / or (nC ₃ H ₇ ) SiCl ₃ are suitable. Particularly preferred is Si (OC ₂ H ₅ ) ₄ .

A further subject is silicone rubber containing coated iron oxide particles according to the invention. The proportion of the particles according to the invention is preferably 0, 1 to 10 wt .-% and particularly preferably 1 to 6 wt .-%, each based on the silicone rubber. In which

Silicone rubber may be HTV silicone rubber, LSR silicone rubber or RTV1 -K silicone sealant. Preferred is an HTV silicone rubber. As further components of the

 Silicone rubber crosslinkers, fillers, catalysts, color pigments,

Anti-stick agents, plasticizers and adhesion promoters included.

Another object of the invention is the use of the

coated iron oxide particles according to the invention as a constituent of

Rubber compounds, being part of polymer preparations, as Component of adhesive compositions, as part of welding in electromagnetic alternating field available

Plastic composite moldings.

The present invention provides particles which are ideally suited for inductive heating. By varying the composition of the iron oxide content, it is possible to set a tailor-made heating rate directed in each case at the object to be heated. The metal oxide shell is a chemical shielding of the magnetic portion of a particle of other magnetic particles, so that agglomeration of the particles can be largely or completely avoided.

Examples

feedstocks

Silica dispersion: It becomes NexSil 12 ™, NYACOL, an aqueous dispersion of colloidal silica particles containing 30% by weight of S1O2, a pH of 10 and a BET surface area of 227 m ² / g used.

Aluminum oxide dispersion: It is NYACOL AL20 ^®, from NYACOL, an aqueous dispersion of colloidal alumina particles with a content of Al2O3 of 20 wt .-%, a pH of 4 and a particle size of 50 nm..

 FeOOH Particles: It becomes acicular alpha goethite particles of the company Kremer pigments with the dimensions 1 = 1 - 3 pm, d = 0.3 - 0.6 pm.

 used.

Dispersions AE: With stirring, first NexSil 12 ™ and K ₂ HPO ₄ , in the case of dispersion E, and subsequently the FeOOH particles are added to water. In the case of dispersion C, CH ₃ OH is subsequently added. Dispersion F: With stirring, first NYACOL AL20 and subsequently the FeOOH particles are added to water.

Table 1: Composition of the dispersions A-F *

* In% by weight; §: Al ₂ O 3 instead of SiO ₂ ; nb = not determined

Example 1: 1000 g / h of dispersion A are atomized with 4.0 Nm ³ / h of nitrogen. The aerosol is mixed with 1, 1 Nm ³ / h of hydrogen (H ₂ -1). This mixture of substances is heated externally. The heat source used is a flame obtained by ignition of a second mixture of 19.0 Nm ³ / h of air (air-2) and 5.0 Nm ³ / h of hydrogen (H ₂ -2). After a mean residence time of 3.0 s, the reaction products of the two mixtures at an existing temperature of 660 ° C and a mean residence time of 2.7 s. Subsequently, it is cooled and the

Product deposited on a filter. The product consists of silica particle coated needles of iron oxide. As iron oxide modifications, magnetite, maghemite and hematite, in a composition calculated as Fe ₂ O ₃ , respectively, of 55: 14:31 are detected. The ratio Fe ₂ O ₃ / SiO ₂ is 90:10. The BET surface area is 10 m ² / g. The leach test gives a value of 26 ppm Fe in solution and indicates a dense silica shell. The heating rate is determined in a silicone composition. The silicone composition is obtained by mixing 33 g ELASTOSIL ^® E50, Fa. Momentive Performance Materials, 13 g of silicone oil type M 1000, Fa. Momentive Performance Materials, 4 g of Aerosil ^® 150, Fa. Evonik Degussa and 2.5 g, equivalent to 4 , 76 wt .-%, of the product from Example 1 by means of a SpeedMixers 2x30 sec. And 2x45 sec. At 3000Upm mixed. Subsequently, the silicone composition is applied in a thickness of about 1 mm on a glass slide. The energy input is made by induction by means of a water-cooled coil. The heating rate up to 100 ° C is 15.4 ° C / s and 1 1, 8 ° C / s to 200 ° C.

Examples 2-5 are carried out analogously to Example 1. Starting materials and operating conditions are given in Table 2. The physicochemical properties of the products obtained are shown in Table 3.

Example 6: 2000 g / h of the dispersion B are atomized with 4.0 Nm ³ / h of nitrogen. The aerosol is mixed with 7.0 Nm ³ / h of hydrogen and 3.3 Nm ³ / h of air (air-1) and ignited. After a mean residence time of 6.4 s, 15.0 Nm ³ / h of air (air-2) are added. The resulting mixture reacts at a temperature of 1057 ° C and a mean residence time of 2.2 s. The resulting mixture is subsequently cooled and the product is deposited on a filter.

The product consists of silica particle coated needles of iron oxide. Magnetite, maghemite and hematite, in a composition calculated as Fe ₂ O ₃ , of 32:15:53, respectively, are detected as iron oxide modifications. The ratio Fe ₂ 0 ₃ / Si0 ₂ is 90:10. The BET surface area is 18 m ² / g. The leach test gives a value of 35 ppm Fe in solution and indicates a dense silica shell.

 The heating rate is determined as described in Example 1.

Examples 7-9 are carried out analogously to Example 6. Starting materials and operating conditions are given in Table 2. The physical Chemical properties of the products obtained are shown in Table 3.

Example 10: 2000 g / h of dispersion E are atomized with 4.0 Nm ³ / h of nitrogen. The aerosol is mixed with 3.0 Nm ³ / h of hydrogen (H ₂ -1) and this first mixture of substances is heated externally. The heat source used is a flame obtained by ignition of a second mixture of 14.6 Nm ³ / h of air (air-2) and 3.0 Nm ³ / h of hydrogen (H ₂ -2). After a mean residence time of 4, 1 s, the resulting from the first and second mixture mixture derived products are combined at an available temperature of 585 ° C and a mean residence time of 2.6 s. Subsequently, 180 g / h of a mixture consisting of 53

Parts by weight TEOS and 47 parts by weight CH ₃ OH injected.

Subsequently, the mixture is cooled and the product is deposited on a filter. The product consists of silica particle coated needles of iron oxide. As iron oxide modifications magnetite, maghemite and hematite, in a composition, calculated in each case as Fe ₂ O 3, of 65:22:13 detected. The Fe ₂ O ₃ / SiO ₂ ratio is 85: 15. The BET surface area is 9 m ² / g. The leach test gives a value of 8 ppm Fe in solution and indicates a dense silica shell.

The heating rate of silicone rubber is determined as described in Example 1.

Examples 1 1 -12 are carried out analogously to Example 10. Starting materials and operating conditions are given in Table 2. The physicochemical properties of the products obtained are shown in Table 3.

Examples 13-14 are carried out analogously to Example 10, but using the dispersion A and those mentioned in Table 2 Amounts of starting materials. The physico-chemical properties of the products obtained are shown in Table 3.

Example 15 is carried out analogously to Example 1, but using dispersion F instead of A. Starting materials and amounts of starting material are reproduced in Table 2. The physico-chemical properties of the products obtained are shown in Table 3.

FIG. 3 shows the heating curve of various compressed powders brought about by induction at 40 kHz. The x-axis shows the induction time in s, the y-axis the temperature in ° C. 1 is the particles according to the invention from example 3, 2 and 3 are commercially available powders. It turns out that with the particles according to the invention the highest temperatures and the best heating rates can be achieved. Also noteworthy is the stability with a longer induction time.

Example 16-3: Silicone rubber formulation

3 phr (parts per hundred rubber) of the particles from Example 10 are incorporated into 100 parts of Silplus 50MP, MOMENTIVE (50 Shore A) and homogenized over a period of 5 minutes. Subsequently, 1.2 parts by weight of di (2,4-dichlorobenzoyl) peroxides DCLBP-50-PSI are added.

Similarly, silicone rubber formulations are prepared at 6 phr, Example 16-6, and 9 phr, Example 16-9. As a comparison serves a formulation without particles, Example 16-0.

 As Table 3 shows, even small amounts cause rapid heating in the alternating electromagnetic field. So is at 3 shares of

Particles according to the invention reaches a temperature of 120 ° C in the high frequency range after about 2 seconds.

 In addition to the excellent properties during induction, the particles according to the invention are also distinguished by their heat-stabilizing properties

Properties off. As shown in Table 4, the

Silicone rubber formulation with only 3 phr particles the best

Properties. Table 2: Starting materials and amounts used in Examples 1-15

c) measured 20 cm before the addition point of TEOS

Table 3: Physical-chemical properties of the products from Examples 1-15

Fe ₂ 03 / Al ₂ 03

Table 3: Induction in alternating electromagnetic field

Example 16-0 16-3 16-6 16-9

Particles from Example 10 phr 0 3 6 9 t tl20 ° C. ^a )

 675 kHz, 23KW s - 2.6 1, 8 1, 4

507 kHz, 8 KW s - 5,4 2,4 2

1.5 MHz, 2.9KW s -1, 45 0.75 0.5

T i max ^b) ° C - / - 62/99 93/158 127/217 a) time to reach a temperature of 120 ° C; b) maximum achievable temperature after 0.5 / 1, 0 s

Table 4: Influence of the powder of Example 10 on the heat stability of a silicone rubber

Example 16A 16B 16C 16D

Particles from Example 10 phr 0 3 6 9

breaking strength

Start N / mm ² 8 7.5 7.9 8.7

7 days / 275 ° CN / mm ² - 5 4 5

Elongation at break% 445 385 395 410

 Start% 445 385 395 410

7 days / 275 ° C% - 140 150 170

Change% - 63 62 58

Claims

claims:

1 . Coated iron oxide particles,

 characterized in that

 they are needle-shaped, having a maghemite and magnetite-comprising core and a metal oxide or metalloid oxide-containing shell.

2. coated iron oxide particles according to claim 1,

 characterized in that

 they have a length of 0.2 to 5.0 pm and a width of 0, 1 to 3 pm, with a length / width ratio of 2: 1 to 20: 1. 3. coated iron oxide particles according to claims 1 or 2,

 characterized in that

 the shell material comprises or consists of silica.

4. coated iron oxide particles according to claims 1 to 3,

 characterized in that

 the iron oxide content further comprises hematite.

5. coated iron oxide particles according to claims 1 to 4,

 characterized in that

the proportion of iron oxide, calculated as Fe ₂ 0 ₃ , 60 to 95 wt .-% and shell material 5 to 40 wt .-% is. 6. coated iron oxide particles according to claims 1 to 5,

 characterized in that

 After 0.33 g of the particles in contact with 20 ml of 1 N for 15 minutes

Hydrochloric acid solution, the hydrochloric acid solution has less than 50 ppm iron. Process for the preparation of the coated iron oxide particles according to

Claims 1 to 6,

characterized in that a) in a high-temperature zone, a needle-shaped FeOOH particles and optionally Hüllstoffpartikel containing aerosol in a reducing gas atmosphere for reaction, and subsequently brings the resulting mixture with an amount of an oxygen-containing gas, preferably air, in contact, which is sufficient Completely oxidizing the mixture of substances and b) if appropriate subsequently at one or more points

 outside of the high temperature zone, add one or more envelope source compounds,

c) where:

 the filler particles in the aerosol according to a) and / or

 Hüllstoff starting compounds according to b) are used, wherein the sum of the Hüllstoffpartikel and the Hüllstoff- starting compounds, calculated as metal oxide or

Metalloid oxide, the amount of metal oxide or metalloid oxide, as it is present in the later coated iron oxide particles, wherein the iron oxide content is calculated as Fe ₂ 03, d) the mixture subsequently cools and separates the solid.

Method according to claim 7,

characterized in that

the high-temperature zone represents a flame which is formed by mixing a mixture of a hydrogen-containing fuel gas and a gas in a reaction chamber spatially separated from the aerosol

oxygen-containing gas ignites. A process for producing the coated acicular iron oxide particles according to claims 1 to 6,

characterized in that a) a mixture comprising a needle-shaped FeOOH particles and optionally aerosol containing Hüllstoffpartikel, a

 containing oxygen-containing gas and excess hydrogen-containing fuel gas by ignition,

b) the mixture further below oxygen-containing gas in excess feeds, and can react in a flame, c) optionally followed by the resulting mixture at one or more locations one or more Hüllstoff- output compounds are added, where

 the filler particles in the aerosol according to a) and / or

 Hüllstoff starting compounds according to c) are used, wherein the sum of the Hüllstoffpartikel and the Hüllstoff- starting compounds, calculated as metal oxide or

Metalloid oxide corresponding to the amount of metal oxide or metalloid oxide present in the later coated iron oxide particle, the iron oxide content being calculated as Fe ₂ O ₃ ,

d) subsequently cools the mixture of substances and separates the solid.

Process according to claims 7 to 9,

characterized in that

the aerosol is produced by atomizing a dispersion which contains acicular FeOOH particles and, if appropriate, filler particles, and an inert carrier gas.

Process according to claims 7 to 10,

characterized in that

the acicular FeOOH particles are doped with at least one element selected from the group consisting of P, Si, Al, Mg, Co, K and Cr.

12. The method according to claim 7 to 1 1,

 characterized in that

 the filler particles are silica particles.

13. Method according to claims 7 to 12,

 characterized in that

one uses as shell material output compound Si (OC2H ₅ ) ₄ .

14. Silicone rubber containing coated iron oxide particles according to

 Claims 1 to 6.

15. Silicone rubber according to claim 14, characterized in that the proportion of the coated iron oxide particles is 1 to 6 wt .-%.

16. Use of the coated iron oxide particles according to claims 1 to 6 as a component of rubber mixtures, as a component of polymer preparations, as a component of adhesive compositions, as part of bodies obtainable by welding in electromagnetic alternating field plastic composite moldings.