DE1447985B2 - Process for the production of magnetogram carriers - Google Patents

Description

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Magnetogram carriers are produced by placing a dispersion of magnetizable material on a carrier Applies particles in a binder and then solidifies the layer. The carrier represents usually a film made of z. B. paper, cellulose acetate, polyvinyl chloride or polyesters. As a binder serve as film-forming substances such as cellulose esters, polyvinyl chloride, polyurethanes or polyamides.

It is known to produce magnetic pigment mixtures for application to a transfer fabric, that of a mixture of the magnetizable particles and a mixture of a rubbery dimethyl silicone polymer and a solid polysiloxane resin as an embrittling component in the binder mixture consists, then on the transfer layer still a wax layer to improve the Sliding properties of the magnetogram carrier is applied (US-PS 30 87 832).

To improve the mechanical properties of magnetogram carriers, in particular to reduce them it is the friction pull that occurs during their sliding movement over the magnetic heads known to add high-polymer dimethylsiloxane to the binder (US Pat. No. 2,654,681). Through this the frictional tension of the belt is reduced, but with such additives Ribbons have other drawbacks. These are mainly due to the fact that the polymeric dimethylsiloxane is more or less poorly compatible with the binders and after some time out of the layer emigrates. As a result, the sound heads of a magnetographic recording apparatus are strong get dirty. At the same time, the adhesive strength of the binder layer on the carrier degraded.

The object was therefore to provide magnetogram carriers that not only improved Have sliding properties, but at the same time also improved endurance properties, i. H. a smaller increase in the coefficient of friction during continuous operation, without impaired adhesion demonstrate. In addition, these magnetogram carriers should have a lower charge during operation, i. H. a better electrical conductivity, and have improved magnetic properties.

It has now been found that this problem can be achieved if one is involved in the manufacture of magnetogram carriers by applying magnetizable particles dispersed in a binder on a carrier and subsequent solidification of the binder, with the Adding an organic silicon compound to the binder, selects a silicon compound through the general formula

is characterized in which η is an integer from 1 to 3, R is one or different aliphatic, optionally unsaturated or aromatic hydrocarbon radicals and X is a halogen and / or alkoxy and / or hydroxyl and / or amino radical, and this compound in one Amount of 0.5 to 26 percent by weight, based on the magnetizable particles, is introduced into the binder.

The compounds mentioned can be added to the binder layer at any stage before they solidify. It is accordingly possible to add these compounds, for example, to the already finished dispersion. However, the compounds are advantageously added during the preparation of the dispersion itself, since they have a favorable effect on the dispersion process. It is particularly advantageous to treat the magnetizable particles with the compounds mentioned before dispersing them, if appropriate in the presence of the dispersing liquid. The binders are then incorporated into these mixtures. The abovementioned compounds have the effect that homogeneous dispersions can be produced in a shorter time than is possible without the abovementioned additives. Possible aliphatic hydrocarbon radicals are essentially those with 1 to 16 carbon atoms, which can optionally also be unsaturated. Compounds with 2 to 4 carbon atoms are particularly favorable. The aromatic hydrocarbon radicals can be, for example, phenyl or naphthyl groups. It is of course possible that, in the case of compounds in which η> than 2, different hydrocarbon radicals can be used for R. Of the ligands denoted by X, halogens and especially alkoxy groups, especially those with up to 4 carbon atoms, have the best effect. The following compounds may be specifically mentioned as suitable silicon compounds: trimethylmonochlorosilane, diethyldichlorosilane, tripropylmonochlorosilane, phenyl methyldichlorosilane, tributylmonoehlorsilan, diphenylmeihylchlorosilane, phenyldiethylchlorosiluene, vinyltrichlorosilane, etc. these compounds can be chlorodichlorosiluene, vinyltrichlorosilan, dimethyldichlorosilan, vinyltrichlorosilan, vinyltrichlorosilan, vinyltrichlorosilan, etc.

Of course, it can also be replaced by an OH group, ethoxy or amino group. For example: Tributyloxyethylsilane, diethoxydimethylsilane, diethylsilanediol, trimethylaminosilane or diethyloctylaminosilane.

Basically, binders that have been customary up to now for the production of magnetogram carriers can be used Binders are used. Particularly good results are achieved when using as a binder Polyamides are used, which in turn are characterized by particularly good mechanical properties. Polyamides which are particularly soluble in solvents and which, based on the total amount by weight, should be mentioned under polyamides based on the polyamides, 50 to 100 percent by weight of linear polyamides forming components with 8 to 20 carbon atoms are polymerized contain. The binder layers can furthermore also contain additives such as dispersing aids in a known manner contain.

As mentioned, the silicon compounds mentioned the binders in an amount of 0.5 to 26 percent by weight, based on that contained in them magnetizable pigment, added. Already in small amounts of 0.5 percent by weight There is a significant improvement in the mechanical and, therefore, also in the magnetic properties watch the magnetogram carrier. In general, the magnetizable layers contain about 0.5 to 5 percent by weight of magnetizable particles. -

By adding these compounds before or during the preparation of the dispersion, you can as already mentioned, very homogeneous dispersions are obtained in shorter times. The finished magnetogram carriers are characterized by high abrasion resistance and good endurance properties themselves strong mechanical stress, as is the case in television recording equipment.

The parts mentioned in the examples represent parts by weight.

example 1

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A) 50 g of acicular γ-iron oxide are mixed with 0.7 g of a copolymer of 80 parts of butyl acrylate and 20 parts of acrylic acid, 1.5 parts of oleic acid monoethanol amide 45 parts of n-propanol and 15 parts of water for 30 minutes in a stirred ball mill dispersed. The agitator runs at 4000 revolutions / minute. The ball mill contains 400 g steel balls with a diameter of 1 mm. Then you put the mixture Add 2.5 g of trimethylsilicon chloride and disperse for a further 30 minutes. Then this mix 63 parts of a 20% solution of a copolymer of caprolactam, adipic acid hexamethylenediamine and sebacic acid hexamethylenediamine in a mixed solvent 80 parts of propanol and 20 parts of water were added and the mixture was added for a further 60 minutes long dispersed.

B) In a further experiment, proceed as described under A), but instead of the Trimethylsilicon chloride added 2.5 g of ethyltriisobutoxysilicon to the mixture.

C) For comparison, an experiment is carried out as already described under A), but is instead of the trimethylsilicon chloride of the mixture, 2.5 g of polydimethylsiloxane according to US Pat 26 54 681 added.

The dispersions obtained according to A), B) and C) are filtered through a paper filter and then applied to a 20 μ thick film made of polyethylene terephthalate to a dry film thickness of 10 μ.

The following table shows the properties of the magnetogram carriers obtained according to A), B) and C) listed:

IA

IB

IC

Surface resistance
[Ohm / cm]
Surface roughness [μ]

10 ⁹ 10 ⁹ 10 ¹⁰
0.2 0.3 0.2

The magnetogram carriers A) and B) show after loading in a television recording machine with a rotating head, no microscopic results after a minute's exposure at the same point Changes in the surface, while in the case of the magnetogram carrier according to C) it is clear in the microscope Scratch marks can be seen.

Example 2

A) 800 g of acicular iron (III) oxide are mixed with 400 ml of ethyl acetate, 400 ml of chlorobenzene and 40 g Phenylmethyldichlorosilicon was ground in a ball mill for 16 hours. This mixture a solution of 92 g of a polyester from 3 moles of adipic acid, 2 moles of 1,3-butylene glycol and 2 moles of hexanetriol and 59 g of a copolymer of vinyl chloride and vinyl acetate in a solvent mixture of 600 ml of ethyl acetate, 600 ml of chlorobenzene and 160 ml of cyclohexanol added and ground for a further 32 hours.

B) The procedure is as under A), but 40 g of one is used instead of phenylmethyldichioresilane Polydimethylsiloxane according to US Pat. No. 2,654,681 is used.

The dispersions obtained according to A) and B) are, as described in Example 1, on a polyester film applied. The coefficient of friction is measured between the magnetic layer and the steel:

2Λ

2 B

Coefficient of friction

0.25 0.32

Example 3

A) 100 g of acicular; iron (III) oxide are mixed with 5 g of the example! 1 described acrylic resin and 150 g of solvent, consisting of 3 parts Methanol. 2 parts benzene and 1 part water dispersed in a ball mill for 60 minutes.

B) The procedure is as described under A), but with the difference that instead of the Acrylic resin 5 g propyltriethoxy silicon is used.

C) The procedure is as described under B), but instead of 5 g of propyltriethylsilane 5 g of a polydimethylsiloxane according to US Pat. No. 2,654,681 are used.

All three approaches are each with 75 g of a 20% solution of a copolyamide from caprolactam, adipic acid-hexamethylenediamine and adipic acid-diaminodicyclohexylmethane mixed in the above-mentioned solvent and dispersed for a further 60 minutes.

As described in Example 1, the dispersions are applied to a polyester film and dried. After drying, they have the following properties:

a) mechanically: Layer tears elasticity (Magnet- dB away Magnetic head ver Ohm / Π Adhesion Strength occasionally from band will to dB adheres pollution (after Ohm / D (Tape sample) Elastic limit stretched) 62 dB 1 minute rotation ¹ ohm / D no shift adheres on the same demolition Magnetic tape position) Layer tears strong A. occasionally from electrical: Magnetic layer jump to the no B. edge pollution layer no C. very good pollution layer b) Well Surface resistance the magnetic layer Noise voltage 10 ⁹ A. distance 10 ^s B. 62.5 10 ¹⁰ C. 63.5 Example 4

20% solution of a copolymer of 80 parts by weight of vinyl chloride and 20 parts by weight of vinyl acetate in a mixture of tetrahydrofuran and toluene (1: 1), 700 g of a mixture of the same Parts by weight of tetrahydrofuran and toluene, 4.5 g of water, 470 g of a 20% strength solution of a polyurethane from adipic acid butanediol polyester and diphenylmethane diisocyanate in the above-mentioned solvent mixture, as

Experiment A: 18 g of polydimethylsiloxane
respectively.

Experiment B: 18 g of trimethyl silicon chloride
(according to the invention)

are dispersed in a ball mill with 4 mm steel balls for 2 days. The resulting magnetic dispersion is filtered and poured onto 36 μm polyester film which has been provided with a vinylidene chloride-acrylonitrile copolymer as an adhesion-promoting intermediate layer. This was done in such a way that a dry film thickness of 12 μm resulted. The magnetic particles are aligned by guiding the cast layer over a suitable alignment magnet. Drying takes place at 6O ⁰ C.

The magnetic layer is compacted by heated steel rollers (190 ^{° C.).} Finally, the magnetic sheet is _{cut to a width of V 4} inches, making a magnetic tape for sound recording.

The tape samples produced in Trials A and B were then tested and showed the following Characteristics:

Trial A Trial B

900 g acicular y-iron (III) oxide, 45 g carbon black with an acidic surface, 36 g soy lecithin, 560 g one

1. Coercive Force (Oe) 255 253

2. Remanence (Gauss) 948 1015

3. Saturation (Gauss) 1290 1385
4. Guide factor 1.7 1.7

5. Sensitivity (dB) +0.6 +0.6

6. Distortion attenuation (dB) 40 40

7. Signal to noise ratio 66 67.5
(dB)

8. Frictional force at 10 10

commercial Sound head (p)

9. Frictional force as in (8), 20 13
but after 1 h of continuous operation (p)

Claims (2)

Patent claims: 1. A method for producing magnetic grams carriers by applying dispersed in a binder magnetizable particles to a substrate and subsequent hardening of the binder, adding an organic silicon compound prior to the solidification of the binder, characterized denotes overall _I0 that a silicon compound is selected by the general formula R _n SiX ₄ -. is characterized in which η is an integer from 1 to 3, R is one or different aliphatic, optionally unsaturated or aromatic hydrocarbon radicals and X is a halogen and / or alkoxy and / or hydroxyl and / or amino radical, and this compound in one Amount of 0.5 to 26 percent by weight, based on the magnetizable particles, is introduced into the binder. 2. The method according to claim 1, characterized in that the compound of the general formula R _n SiX ₄ - ,, optionally in the presence of a solvent, mixed with the magnetizable particles.