DE1190985B - Magnetic recording medium with two magnetic layers - Google Patents

Description

Magnetic recording medium with two magnetic layers The invention concerns the improvement of the electroacoustic properties of a magnetic tape, especially for the simultaneous recording of television signals and audio frequencies is used according to the four-head Ampex process, consisting of a plastic carrier with an iron oxide layer in which the iron oxide crystals are preferably needle-shaped Have shape. During the watering, these needle crystals are still moist in the Magnetic layer exposed to a magnetic field to turn them all in a desired direction orient them in parallel and by evaporation of the solvent they are in this parallel position to fix. As is known, this measure increases the magnetic properties improved in the direction of orientation, but at the expense of the other directions, especially perpendicular to the direction of orientation, in which it deteriorates to the same extent will.

When recording the video signal magnetically using the Ampex four-head method is on a 2 "wide magnetic tape moving at a speed v of 38 cm / s is transported, the video track is laid down transversely to the longitudinal axis of the tape by four magnetic heads, which are offset by 90 ° on the circumference of a cylindrical and rapidly rotating Drum are arranged on the with the help of a suitable guide in the longitudinal direction Grind the cylindrically curved belt in such a way that each head is from above moved down across the width of the belt. Just before the first head on his Leaves the belt way from top to bottom, the second head already touches the upper one Edge of the tape. The same is repeated with the third and fourth head, so that the time sequence of the video signal, with a certain overlap area on the upper and lower edge of the tape, continuously along the transverse magnetic tracks is laid down.

The angle of inclination of these magnetic tracks results from the two movement components, namely the transport speed of the tape of v1 = 38 cm / s in the longitudinal direction and the peripheral speed of the head drum of approximately v2 = 40 m / s and is around 1/2 ° (more precisely 32 minutes 40 seconds), d. That is, the magnetic track is practically in place perpendicular to the longitudinal axis of the belt. The sound, on the other hand, is at the top of the tape in a width of around 2 mm recorded as a longitudinal track. It will be shortly before written video track in the overlap area of the rotating heads deleted. Of the Overlap area at the bottom of the tape is used to record a Clock track used for the synchronous run during playback by adding to this Place 240 Hz square-wave pulses lengthways on a track about 2 mm wide of the tape. They act like an electrical perforation. That Video signal for recording, consisting of the image signals and the Line or Image change impulses. is frequency-modulated in a modulator Signal converted, with the frequency deviation ranging from about 4 to 7 MHz.

The frequency range of variation of the frequency-modulated signal is therefore not quite an octave. The information content of the video signal, however ranges from 50 Hz (field alternating frequency) to about 6 MHz and therefore comprises seventeen Octaves.

During playback, the sampled frequency-modulation mixture is reconverted to the amplitude-modulated video signal in a demodulator.

The wavelengths A, of the recorded frequency-modulated video frequencies f from 4 to 7 MHz are also calculated if v = 40 m / s the peripheral speed of the rotating heads is - 40 - 106 ym / s = 10 #Lm for 4 MHz 4. 10, 1 / s or A = 5.7 t, m for f = 7 MHz .

The frequencies of the sound recording range from 30 Hz to 15 kHz, i.e. extend over nine octaves. The corresponding wavelengths range from 12.7 mm to 25 Vm at a longitudinal tape speed of 38 cm / s Wavelengths of e.g. B. more than 1 mm to 0o = IR-q-Fv [M], if IR is the remanent induction, q = b - d is the cross-section of the magnetic layer in square centimeters with the thickness d and the track width b and Fv the volume fill factor, i.e. that The ratio of the volume of iron oxide to the total volume of the magnetic layer is. In the case of magnetic layers, it is on average about 30 ° / 0, in the most favorable case 40 11/0.

If one extends this equation by introducing the saturation magnetization IS, one obtains The expression is related to the saturation magnetization Remanence or the relative Reo = @ Is-bd-Fv = 0.85-4-103.10-1.10-3 N0.1 [M / mm] if the tape is magnetized to saturation, as is the case with video recording. In the case of sound recording, on the other hand, due to the linear distortion, only about half the saturation flow can be controlled so that the distortion factor remains below 3 ° / a. The usable foot at this full level is then In the known magnetic tapes for video recording, use is made of this possibility of pre-orienting the needle oxides to increase the flow for video recording, in that the orientation is carried out perpendicular to the longitudinal axis of the tape. Such tapes give the video signal greater head tension and better signal to noise ratio. However, at the same time the magnetic flux in the longitudinal direction is reduced by a factor of 2, because the relative remanence in this direction is only around 42%.

The sound recording, which takes place in the longitudinal direction of the tape, is therefore reduced in quality by increasing the non-linear distortion (Distortion factor K3 increases), which leads to a reduction in the dynamics (distance between the useful voltage to interference voltage) and the copying effect increases.

To eliminate these disadvantages it has already been proposed the top and bottom of the 50.8 mm (2 inch) wide tape in one width of around 3 mm in the longitudinal direction, but the remaining width of the tape in the transverse direction to orient. In practice, however, there are great difficulties in cutting of the tape from a larger width exactly the tolerances for the overlap area of the video signal or the exact width of the longitudinally oriented and optically not recognizable edge marks must be observed. The consequence of this are volume fluctuations the sound track or fluctuations in the signal-to-noise ratio of the first and last picture lines manence. It is also called the square factor of the hysteresis loop (see A b b. 1, in which the hysteresis loop of a non-oriented iron oxide layer is shown is). The saturation magnetization 1s is magnetizable for a given Substance is a constant and is around 4000 Gauss for the iron oxide y-Fe303.

The relative remanence is in needle-shaped oxides without orientation around 60% and can be increased to around 850% by aligning the needles in parallel. However, the relative remanence then drops to about 42% perpendicular to this preferred direction. These ratios are for three hysteresis loops in A b b. 2, where 1 applies to the non-directional, 2 to the longitudinally oriented and 3 to the transverse directional magnetic layer.

A 10 #tm thick magnetic layer would be per millimeter of track width a retentive saturation band flow of the total of sixteen lines that the single head records or scans when running from the top to the lower edge of the tape.

It has now been found that the above-mentioned disadvantages can be eliminated in a technically simple manner if a magnetic tape is used for the video recordings which contains two magnetizable layers on a carrier. This special tape is produced by first applying a magnetic layer 5 of about 10 to 12 µm to the base 6 and orienting it in the longitudinal direction of the tape. After this magnetic layer has dried on, a second layer 4 of about 1.5 to a maximum of 2 μm is poured on, and this is oriented perpendicular to the longitudinal axis of the tape, as shown in A b b. 3 is shown.

Both layers with perpendicular orientation of the Magnetic particles extend over the entire width of the doused path. From this can be followed exactly without any restrictions as to a Track, as required by the known method, the tapes in the desired width get cut.

The production of a magnetic recording medium according to Invention, is described in the following example.

Example 8 kg acicular γ-ferric oxide (particle length about 0.8 μm, particle width about 0.1 μm) with a saturation remanence of 420 gauss - cm 3 - g 1 and a coercive force X i; von 270 Oerstedt are in a solution of 921 g of polyester from 3 moles of adipic acid, 2 moles of 1,3-butylene glycol and 2 moles of hexanetriol and 590 g of copolymer of polyvinyl chloride and polyvinyl acetate (corresponding to 20 percent by volume of the total paint content) in 10.251 ethyl acetate, 10.25 l chlorobenzene and 1.61 cyclohexanone ground in a ball mill for 48 hours.

The iron oxide lacquer suspension obtained in this way is after addition of 1230 g hexamethylene diisocyanate, which partially implemented with hexanetriol is, on a 25 uni thick polyester film (based on terephthalic acid and ethylene glycol) infused. The thickness of the dry layer is 12 am with an iron oxide content of 27 g / m2. This results in a volume fill factor of 39.6 ° / a.

By the action of a homogeneous magnetic field with a field strength of about 1000 Oerstedt the iron oxide particles are before the drying of the binder aligned in the direction of travel of the belt.

A second layer of the same structure is applied to this layer, however, poured in such a way that the resulting dry layer has a layer thickness of 2 a.m. This layer is applied before drying the binder, as described above, but aligned magnetically in the transverse direction of the tape.

The invention is based on the utilization of the wavelength-dependent band flow attenuation based on a magnetic layer. This causes a homogeneously magnetized Magnetic layer the entire tape flux at small wavelengths regardless of the thickness of the magnetic layer and at a wavelength of about 10 µm, the largest wavelength of the frequency-modulated video signal mixture, only through a thin surface layer of the band of about 1.6 u.m, while the remaining larger part of the Magnetic layer thickness due to the exponential law of distance between strip magnetization and playback head does not contribute to the overall flow.

If the flux at a long wavelength (J greater than 1 mm) is denoted by 0o, the tape flux (P at wavelength 2) follows, on the practically correct assumption that the initial permeability of the layer is u, -1, and the magnetic layer with the Thickness d in contact with the playback head is the law of distance: This means that a magnetic layer thickness of z. B. d = 10 u, m for a wavelength A, = 10 um the flux fi at this wavelength because of = 1 on is reduced. If 0, the flux is at long wavelengths. Since one can write tho = IR.bdFi for the flux at large wavelengths, one can assign an effective layer thickness b to the flux at small wavelengths, ie that determines this flux, and write rh = Ir.bbFv. Dividing the second equation by the first one obtains the trivial statement that the flow is proportional to the layer thickness. The effective layer thickness A at the shaft length.? is therefore proportional to the flux at that wavelength The effective layer thickness A is therefore for = 1 ie that z. B. from a magnetic layer with a total thickness d = 10 .mu.m only 1.6 .mu.m of the surface generates the entire flux at the largest video wavelength of 10 .mu.m.

Damanden expression e can be neglected for layer thicknesses greater than 5 μm at the wavelengths under consideration, the result is that the effective layer thickness in this area is independent of the thickness of the entire magnetic layer. and only depends on the wavelength Z. For the recording of video wavelengths of 10 to 5.7 μm, layer thicknesses according to the invention which are oriented in the transverse direction of 1.6 to 0.9 t-.m are therefore sufficient. This connection is shown in A b b. 4 across the wavelength. respectively. shown as parameters for different layer thicknesses.

The use of magnetic materials with several magnetic layers having different magnetic properties is known from British patent specification 671269 . The magnetic layers do not differ in terms of the orientation of the magnetic particles contained therein, but in terms of magnetic properties. This is intended to achieve good reproduction of both weak and strong magnetic fields.

If necessary, the transversely oriented top layer can also be thicker to get voted. Even if the layer thickness of the two layers is the same, remains the advantage for video recording, and that for sound recording The effective total layer thickness is still that of a single layer that is only transversely oriented think. Preferably, however, the upper layer will not be larger than 2 u, m, while the total layer thickness is about 12 to 15 µm, in order to achieve optimal electroacoustic Properties can also be maintained in the longitudinal direction.

A video magnetic tape made according to this inventive concept showed a considerable amount compared to a customary, only transversely oriented single layer superior sound quality and improved copy attenuation with the same optimal Video quality.

Claims (3)

Claims: 1. Magnetic recording medium consisting of a non-magnetizable base and two magnetizable layers, d a d u r c h characterized in that the magnetic particles of the two magnetizable Layers are magnetically oriented approximately perpendicular to one another. 2. Magnetic Record carrier according to Claim 1, characterized in that the arranged first magnetizable layer in the longitudinal direction of the tape and the upper second magnetizable layer magnetically aligned perpendicular to the longitudinal axis of the tape is. 3. Magnetic recording medium according to claim 2, characterized in that the magnetizable layer oriented in the longitudinal direction of the tape has a thickness of 8 to 18 μm and the magnetizable layer oriented in the transverse direction has a thickness of 1.5 to 2 μm. References considered: British Patent No. 671269.