NL8201080A - CASSETTE FOR A TIRE. - Google Patents

Description

? _ _ ♦ -1- 22417 / Vk / mb

Short designation: Cassette for a tape.

The invention relates to a cassette for a tape (tape cassette).

The currently available tapes cassettes of general use, for example coplanar audio tape cassettes, consist of a housing made of a hard plastic material and formed with a window at the front for insertion of a magnetic head, and with a magnetic tape arranged in the housing so that it is moved back and forth between a pair of reels on which this tape is alternately applied. A shielding plate for covering the head when the head is inserted into the cassette is disposed within the housing at the location where the head is inserted and an elastic plate is further provided to press the tape against the magnetic head 15, which elastic plate is placed between the shielding plate and the magnetic tape.

The shielding plate serves to protect the magnetic head from the influence of the magnetic field and has hitherto been manufactured from a relatively thick plate of Permalloy (containing 60-90 ^ nickel and the remaining 20 iron) or from a silicon iron alloy with a high magnetic permeability.

One of the objects of the invention is to obtain a cassette for a tape that is lightweight, easy to manufacture and low in noise, which can be accomplished by improving the shield plate mentioned above. This can be achieved by a cassette according to the invention and it is characterized in that the cassette consists of a housing with an opening or window for inserting a magnetic head, a magnetic tape arranged in the housing, wound on at least one reel and with the active side facing outwards, which magnetic tape in the housing can run past the window and a shielding plate disposed in the housing opposite the window with the tape between them, which shielding plate is made of an amorphous alloy of a magnetic material, which amorphous alloy is represented by formula (Co Fe.M), Y or by abc 1-mm formula (Fe ^ ^ M ^) ^ n ^ n (where M is at least one element selected from the group consisting of Ti, V, Cr, Mn, Ni, Zr, Nb, Mo, Ru, Hf, Ta, W and Re, Y is at least one element selected from the group consisting of Si, B, C and P, 0.005é b <0, 15, 0 éo ê0.15, a + b + c * 1, 20430, 8201080 •. V -2- 22417 / Vk / mb 0.01 <d §0.30 and 13 & Π 4.30) -

The invention is further elucidated with reference to the following description, with reference to the appended drawing, in which fig. 1 is a top view of the interior of the tape cassette according to the invention and fig. 2A and 2B are perspective views of the shield plates used in the tape cassette according to the invention.

A relatively thick shielding plate is used in known tape cassettes, which are usually made of Permalloy 10 or a silica iron alloy, while according to the invention this shielding plate is made of an amorphous alloy such as a soft magnetic material, whereby the characteristics of the shielding plate are improved and a tape cassette is obtained which is lighter in weight and easier to manufacture.

The amorphous alloy, unlike a crystalline metal, has no periodicity with respect to crystals. Therefore, it is possible to obtain various properties that cannot be obtained with a crystalline metal. In particular, these alloys have a high magnetic permeability, are better in hardness and mechanical strength, have toughness, can be bent at an angle of 180 °, and can be easily stamped with a press.

In the course of the investigation, various experiments and assays have been conducted with such amorphous alloys with regard to their suitability for a tape cassette shield plate and it has been found that with these plates made from compositions represented by formula 1: (Co Fe.M), Y 1.

a b c 1-m ra or of formula 2: 30 (Fe, .M.), Y 2.

J 1-d d 1-n n shielding plates can be obtained which have considerably better properties.

In the above formulas 1 and 2, M is at least one element selected from the group consisting of Ti, V, Cr, Mn, Ni, Zr, Nb, 35 Mo, Ru, Hf, Ta, W and Re, Y is ten least one element selected from the group consisting of Si, B, C and P, 0.0054 b <0.15, 0écio, 15, a + b + c = 1.20 A m é 30, 0.01 <d έ 30 and 134 n 430.

8201080 _3_ 22417 / Vk / mb r «

The amorphous alloy of formula 1 includes the following compositions: (Co Fe. Ni Nb,). Y 1a a b c d 1-x x

where Y = Si + B

5 22 4x427 a + b + c + d = 1 0.044 b 40.08 0.01 4c 4o, 05.

0.01 4 d 4 0.05 (Co Fe. Cr). Y 1b · a b c 1-x x

where Y = Si + B

224 x 4 27 a + b + c = 1 0.04 4 b4 0.08 15 0.014 cè0.10

The amorphous alloy of formula 1a is preferred in view of its heat stability and high magnetic permeability, while the amorphous alloy of formula 1b is preferred in view of its corrosion resistance.

Examples of the amorphous alloy of formula 1 are: (Co0,9HFe0,03Mn0,03 ^ 75Si10B15 = 37,000 b1 ^ 1 kHz) »(Co0l88Fe0,06Ni0,04Nb0,02) 75Sl10Bl5 s 4,300 bi ^ 1 kHz ^ and ^ Co0, 90Fe0.06Cr0.04 ^ 75Sl10B15 "39-000 @ 1 kHz).

The amorphous alloy of formula 2 comprises the following compositions: (Fe-Nb), Y 2a.

1-aa 1-xx where Y = Si + B 154x425 30 0.024 a 40.10 (Fe, Cr), Y 2b 1-aa 1-xx where Y = Si + B 154x4 25 0.02 éaéO, 10 35 formula 2c- 8201080 «· · *» -4- 22417 / Vk / rab «2 ° where Υ = Si + Β 15é x425 a + b + cs 1 5 0,1ÉbkO, 25 0,02 kckO, 10 (tVWi-xYx 2a

where Y = Si + B

15 = x = 25 10 a + b + c = 1 0.14b 40.25 0.02 έ c = 0.10

Examples of the amorphous alloy of formula 2 are: tFe0,925Cr0,075) 83Sl5B12 ^ 0 = 12'000 at 1 kHz) and 15 ^ 925 ^ 075 ^ 131 ^ ^ = 1 ° 500 WJ 1 kHz)

The amorphous alloy can be obtained by various methods, and the most suitable method is to obtain a band-like amorphous alloy by a continuous quench operation, i.e. a continuous cooling operation of an alloy in a liquid state. Examples of such continuous cooling operations are a centrifugal operation, a single roll process and a double roll process, and of these processes the single roll operation can be very easily performed. The amorphous alloy tape obtained in this way has a thickness of 20 to 60 pn.

It has been found that the magnetic permeability of the amorphous alloy obtained in this way can be further improved by performing a heat treatment at a temperature which does not result in crystallization, i.e. up to a temperature range above the Curie temperature and below the crystallization temperature of the alloy.

Such an amorphous alloy tape is die-pressed to a predetermined shape, usually a rectangular shape, to obtain the shield plate of the invention.

An audio tape cassette in which such a shielding plate is made, made of an amorphous alloy according to the invention, will now be described in more detail, with reference to the attached drawing.

8201080> * τ »-5- 22417 / Vk / mb t

Fig. 1 shows a tape cassette 10 consisting of a hard plastic housing 11 formed at the front with an opening or window 12 for insertion of an erasing head, a window 13 for insertion of a recording / playback head and a window 14 for a pressure roller.

5 A magnetic tape 17 is wound on a pair of hubs 15 and 16 mounted inside the housing with the active side facing outwards and this tape passes over the guide rollers 18 and 19 and along the individual windows 12, 13 and 14. Inside the on the inside of tape 17, an elastic plate (usually a phosphor bronze plate) 20 is provided opposite window 13 for inserting the record / playback head so that when the magnetic head (not shown) is inserted into window 13, tire is pressed against the head. The elastic plate 20 is provided with a pressure pad 21 which is brought into contact with tape 17.

On the back of the elastic plate 20 there is provided a shielding plate 22 made of an amorphous alloy, as indicated above, according to the invention, which is secured by means of opposite holders 23a and 23b.

The invention will be further elucidated by means of the following example.

20 Example

An amorphous alloy tape (50 µm thickness) obtained by sudden cooling with liquid and having a composition represented by formula (%> 88F% 06NVo4NbO, 02) 75 ^ 1013 ^ was pressed to obtain a right angle shield plate which was then 25 was placed in the tape cassette as shown in Fig. 1. As an elastic plate, a phosphor bronze plate was used This tape cassette was placed in a recorder and the noise level was measured For comparison, such noise levels were measured using a tape cassette without shielding plate (equation 1) and using a tape cassette containing a known shielding plate consisting of

Si-Fe alloy (0.3mm thickness) further indicated as (Equation 2). The result of the measurements is shown in the table.

noise level

According to the invention 5 mV

equation 1 15 mV

equation 2 5 mV

8201080 -6- 22417 / Vk / mb

It will be clear that the shielding plate according to the invention has substantially the same magnetic shielding effect as the known Si-Fe alloy-containing shielding plate, despite the fact that the thickness is considerably smaller. This shows that the shielding plate according to the invention is effective despite the fact that less material is used and wherein the weight of the tape cassette can also be reduced.

While the above example illustrates an audio cassette tape, it will be appreciated that the invention is also applicable to any other mechanism where a tape is pressed against a magnetic head. Furthermore, the construction can be simplified by applying the shielding plate to the elastic plate 20 using spot welding or using an adhesive. Furthermore, the amorphous thin plate 22 made of an alloy can be introduced into a cold-setting thermosetting resin such as an epoxy resin 30 and the resin can be cured to obtain a shielding plate with a thickness of 0.3 to 0.8 mm such as shown in Fig. 2A. Alternatively, the amorphous alloy thin sheet 22 can be bonded to either side of such a hardened plastic sheet 30 as shown in FIG. 2B.

In summary, it can therefore be stated that according to the invention a tape cassette is obtained consisting of a housing 11 with a frame 13 for inserting a magnetic head, a magnetic tape 17 arranged in housing 11, which tape is wound on at least one 25 reel (15,16), and with the active side facing outwards, which magnetic tape (17) is driven inside the housing (11) and along window (13) and a shield plate (22) is arranged inside the housing opposite the window behind the tape. The shield plate (22) is made of an amorphous alloy of a magnetic material. The amorphous alloy is shown

30 by formula (Co Fe. M). Y or formula (Fe „.Μ.), Y, where M ten J a b c 1-m m 1-d d 1-n n J

at least one of the elements is selected from the group consisting of Ti, V, Cr, Mn, Ni, Zr, Nb, Mo, Ru, Hf, Ta, W and Re, Y at least one element is selected from a group consisting of Si, B, C and P, 0.005 £ b 40.15, 0 Éc = 0.15, a + b + c - 1.20 £ m & 30, 35 0.014 dè. 0.30 and 13 = nè30.

- CONCLUSIONS - 8201080

Claims (11)

1. Cassette for a tape, characterized in that the cassette consists of a housing with an opening or window for inserting a magnetic head, a magnetic tape arranged in the housing, wound on at least one reel and with the active side facing the outside, which magnetic tape can run in the housing past the window and a shielding plate arranged in the housing opposite the window with the tape between them, which shielding plate is made of an amorphous alloy of a magnetic material, which is amorphous alloy is represented by formula (Co Fe.M), Y or formula (Fe,, M,), Y, abel-mm 1-ddl-nn where M is at least one element selected from the group consisting of Ti, V, Cr, Mn, Ni, Zr, Nb, Mo, Ru, Hf, Ta, W and Re, Y at least one element is selected from the group consisting of Si, B, C and P, 0.005 Feb * 0.15, Oé c = 0.15, a + b + c = 1, 20émé30, 0.01 d 40.30 and 13 = n έ 30. Cassette according to claim 1, characterized in that it further comprises an elastic plate arranged in front of the shielding plate. 2o Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: (Co Fe. Ni Nb.), Y abc d 1-xx where Y = Si + B 22 Éx = 27 25 a + btc + d = 1 0.04 4bet 0.08 0.01ec0.05 0.01 = d = 0.05 4. Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: (Co Fe, Cr 4), Y abo 1-xx where Y = Si + B 22 4 x 427 a + b + c = 1 35 0.04 4 b 4 0.08 0.014 c éo, 10 8201080 t - * * · -8- 22417 / Vk / mb Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: (Fe. Nb) Y 1-a a 1-x x where. Y = Si + B 5 15 é x = 25 0.02 4a 40.10 Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: (Fe. Cr). Y 1-a a 1-x x 10 where Y = Si + B 15.x = 25 0.02 £ ak0.10 Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: 15 (Fe Ni, Nb). Y abc 1-x x where Y = Si + B 15.x kZ5 a + b + c = 1 0.1 έ-b 4θ, 25 20 0.02 ^ c ^ 0.10 Cassette according to claim 1, characterized in that the amorphous alloy has a composition corresponding to: (Fe Ni, Cr). Y a b e 1-x x where Y = Si + B 25 15éx | 25 a + b + c a 1 0.1 kb = 0.25 0.02 4c 40.10 9. Cassette according to claim 2, characterized in that the amorphous alloy is selected from a group of compounds consisting of: (%, 94%, 03%, 03% Sl10B15 '(Co0.88%, 06 ^ 0, 04 ^ 0.02 ^ 75 ^ 108 ^ en (%, 90%, 06%, 045 75Si 10B15 * 10. Cassette according to claim 2, characterized in that the amorphous alloy is selected from a group consisting of (%, 925%, 025 ^ 3% 112 and (Fe0.925Nb0.075 %%% ') Cassette according to claims 1-10, characterized in that the elastic plate is made of a phosphor bronze plate. 2 Ö 1 ö 8 0 Eindhoven, March 1982