NO155167B - Tape cassette. - Google Patents

Description

The present invention generally relates to tape cassettes and more particularly to a tape cassette for use in an apparatus for recording and/or playback, which apparatus comprises a feed reel drive shaft and a take-up reel drive, the tape cassette comprising a cassette housing, a feed-side reel with flange and hub, and a take-up side reel with a flange member and a second hub with a central hole, arranged in the cassette housing for winding a tape, where the winding-side reel's flange member has an engagement member which is placed laterally in relation to the cassette housing, and where the feed-side reel's hub has coupling means formed in its bottom center, in that the engagement member directly engages with the take-up reel drive member and the coupling members engage with the feed reel drive shaft when the tape cassette is placed in the apparatus.

The practical use of apparatus for recording and/or playback of video signals using tape cassettes is currently limited worldwide. There are now two or three standardized device types worldwide. Devices of different standards cannot be used interchangeably, but devices within the same standard can be used interchangeably. A cassette tape recorded in a device for recording and/or playback can therefore be played in another device for recording and/or playback of the same standard. In order to ensure that different devices for recording and/or playback produced by different manufacturers can be used interchangeably for recording and/or playback, a standardization or norming has therefore been established regarding the format of tape cassettes and devices for recording and/or playback. This means that the aforementioned formats are standardized for each standard or norm, and that a tape cassette of a standard type and a device of a standard type are provided for recording/playback for each norm.

In recent times, the problem of reducing the size of the main body of apparatus for recording and/or playback has taken on great importance. It is necessary to produce a more compact, portable device type for recording and/or playback and e.g. to provide such equipment where a recorder is integrally built into a TV camera.

In this regard, attempts have been made to provide a compact type of apparatus for recording and/or playback, which uses a compact or miniature tape cassette, which has a tape pattern and a format that deviates completely from the standard apparatus for recording and/or playback, and which uses cassettes of a standard type that are already on the market and are widely accepted. However, the mentioned compact device type for recording/playback that has been attempted uses a format that is completely different from the standard device for recording and/or playback, and it is not possible to use the devices interchangeably. This compact device type for recording/playback therefore has a disadvantage, in that a tape cassette recorded by the compact device cannot be played back in a standard device for recording and/or playback. This is a major disadvantage for the owners of the compact device type.

Another attempt has also been made to provide a compact, portable device type for recording and/or playback, where recording and/or playback is carried out with the same tape pattern and format as with the standard device for recording/playback, where a tape cassette with a slightly reduced size in that the amount of tape and the spool diameter are somewhat reduced compared to tape cassettes of the standard type. In this system, a tape cassette placed in the portable recording/playback device can be played back as it is by a standard device.

However, in the case of the tape cassettes used in the above-mentioned portable apparatus for recording and/or playback, the distance between a

coil on the unwinding side and a coil on the rewinding side equal to the distance between the coils on the unwinding or rewinding side in standard cassettes, so that the tape cassette used in the portable device can also be placed in a standard type device. Even if the amount of tape is reduced in order to reduce the coil diameter, there is thus a limit to how much the diameter of these coils can be reduced. This system therefore has the disadvantage that the size of the tape cassette as a whole could not be noticeably reduced, and the same applies to the apparatus for recording and/or playback.

There is another system, where the amount of tape is reduced so that the diameter of the coils is reduced. The miniature tape cassette is further constructed by reducing the distance between the unwind reel and the rewind reel. With this system, the standard apparatus can be modified by being designed so that a spool disc for operating the take-up reel is movable. With this modification of the standard apparatus for recording and/or unwinding, the spool disc on the take-up side has a normal position when it is equipped with a tape cassette of the standard type and is moved to a position closer to the unwind side spool when used for a miniature tape cassette.

But even in this system there are e.g. It is unfortunate that a tape cassette recorded in the compact device type for recording and/or playback cannot be played back in the standard device type for recording and/or playback which is currently widely used. It is also a disadvantage that it is extremely difficult to provide a mechanism for moving the coil disk in the above-mentioned manner. The apparatus for recording and/or playback where the tape cassette is used also generally has a mechanism for extracting the tape from the tape cassette in order to guide the tape in a specific tape path in the apparatus. Therefore, it is also very difficult to construct the above-mentioned mechanism for extracting the tape so that it becomes possible to use the compact or miniature tape cassette interchangeably with standard cassettes. The realization of such a mechanism is practically impossible.

It is consequently a main purpose of the present invention to provide a new and suitable miniature tape cassette, in which the above-mentioned disadvantages are overcome. The purpose is achieved by a cassette of the type indicated at the outset, which includes the features specified in patent claim 1.

According to the present invention, a tape cassette of the type mentioned above is also provided, the so-called "wow" and "flutter" of the tape can be kept within the range given for standard tape cassettes.

The way the feed-side spool is driven will greatly affect the ribbon's wow and flutter. On the other hand, the manner in which the recording side coil is driven will not greatly affect the aforementioned effects on the tape.

Accordingly, in order to minimize wow and flutter for the belt, the supply side spool is constructed with a relatively large diameter for hub and flange, while at the same time connecting means are provided at the bottom of the center point of the flange. The coupling member is arranged to directly engage the supply coil drive shaft of the apparatus for recording/or playback.

Furthermore, the recording side coil, which is less related to the wow and flutter issues, is constructed with a relatively small diameter as far as the hub is concerned and with a center hole in the hub, at the same time as having a relatively small diameter flange and with engaging means arranged to the side in relation to the cassette housing. The center hole fits on a shaft mounted on a base plate of the cassette housing, and the take-up side coil is rotatably mounted on the shaft. When the tape cassette is guided inside the device, the engagement members on the flange will engage with the device's drive member.

Because the tape cassette according to the present invention is constructed as discussed above, the following beneficial effects are achieved: a) Because a center drive system for a standard recording and/or playback system is adapted at the supply side coil which greatly affects wow and flutter for the belt, accurate belt travel can be achieved and maintained. b) Because an edge-drive system is used on the recording coil which affects wow and flutter to a lesser extent, the dimension can

of the take-up reel is made very small without a corresponding reduction in the amount of magnetic tape that can be wound onto the take-up reel, resulting in an effective reduction of the size of the tape cassette housing.

c) Because a center drive system is used on the supply side reel, the tape cassette according to the present invention can satisfy compatibility with standard type tape cassettes when used with an adapter.

Other objects and further features of the present invention will be apparent from the detailed description below with reference to the drawing, where

fig. 1A-1D respectively are a plan view, a side view, a bottom view and a rear view, showing a miniature tape cassette as an embodiment of the present invention,

fig. 2 is an elevation showing the tape cassette according to fig. IA in a state where the upper half of the tape cassette is removed,

fig. 3 is a perspective view showing a section of the tape cassette according to fig. IA following the line III-III,

fig. 4A and 4B are sections along the line IVA-IVA and the line IVB-IVB in fig. 2 and shows a connecting part between a support shaft for the reel on the winding side or the lower half of the tape cassette in a disassembled state,

fig. 5 is a view on a larger scale, showing a brake mechanism part for the reel on the winding side, as shown in FIG. 2,

fig. 6 is a rendering in perspective section along the line VI-VI in fig. 5 and shows the brake mechanism according to fig. 5,

fig. 7 and 8 are an elevation and a bottom view, respectively, showing the lower half of an exemplary embodiment of a tape cassette adapter where the tape cassette according to fig. IA is placed,

fig. 9 is an elevation showing a state where the tape cassette as shown in fig. 1A-1D are located in the lower half of the tape cartridge adapter as shown in fig. 7 and the tape is pulled out of the tape cassette to form a fixed tape path,

fig. 10 is an elevational view showing the tape cartridge adapter in a

condition, where the upper half is mounted on the lower half of the tape cartridge adapter, which is in the condition shown in fig. 9 to record the tape cassette,

fig. 11 is a section along the line XI-XI in fig. 10 of the tape cartridge adapter, where the cartridge is omitted,

fig. 12 is an elevation showing an example of a compact apparatus for recording and/or playback, which is exclusively intended for the miniature tape cassette and is in use together with a tape cassette as shown in fig. IA, in a state where the compact device is set for recording or playback,

fig. 13 is a plan view showing an example of a standard recording and/or playback apparatus used with the tape cassette adapter with a tape cassette as shown in FIG. 10, in a trlstand, where the standard device is set for recording or playback,

fig. 14 is an elevation showing another embodiment of a tape cassette according to the present invention in a state where the upper half of the tape cassette is dismantled,

fig. 15 is a section along the line XV-XV in fig. 14,

fig. 16 and 17 show a side view and a bottom view of the tape cassette as shown in fig. 14,

fig. 18 is an elevation showing the lower half of an embodiment of a tape cassette adapter, where the tape cassette as shown in fig. 14 is placed and

fig. 19 is an elevation showing a state where the tape cassette as shown in fig. 14 is placed in the lower half which is shown in fig. 18.

A tape cassette 10 of the miniature type according to the present invention has a shape which is shown in fig. 1A-1D, 2 and 3. The tape cassette 10 comprises a cassette housing 11 of a smaller size than a standard tape cassette which is placed in a standard apparatus for recording and/or playback of video signals. A cover 13 is arranged on the front surface of the cassette housing 11 in such a way that the cover 13 can freely open and close to protect the magnetic tape 12 which is occupied in the tape cassette 10.

The cassette housing 11 consists of an upper half 14 and a lower half 15. The cover 13 is molded from a resin, such as polypropylene, and is mounted on the upper half 14. A front cover part 16 of the cover 13 can rotate about a hinge part 17 which is arranged in the thin, molded corner part of the cover 13. Said front cover part 16 is influenced by a leaf spring 18 towards the closed position to cover the front of the cassette housing 11. When the tape cassette 10 is not placed in a tape cassette adapter or an apparatus for recording and/or playing back video signals, which is exclusively intended for tape cassettes 10 (the adapter and apparatus will be discussed in more detail below), the front cover part 16 will cover the front of the cassette housing 11 to protect the magnetic tape 12 which is exposed to this surface. A finger 19, which is formed on the front cover part 16, also engages in an opening 20 in the lower half 15, so that the front cover part 16 is locked in the closed state.

As shown in fig. 2 and 3, a unwinding coil 21 on the unwinding side and a winding coil 22 on the winding side are also arranged in a parallel manner in the cassette housing 11. A distance D between the respective centers of the unwinding and winding coils 21 and 22 is shorter than the distance between the centers, of the rewind and rewind reels in the standard tape cassettes used in standard recording/playback devices. In the case of the unwinding coil 21, the magnetic band 12 is wound around a coil hub 25 between upper and lower flanges 23 and 24. In the case of the rewind coil 22, the magnetic band 12 is similarly wound around a coil hub 28 between the upper and lower flanges 26 and 27. The magnetic band 12 is pulled by the unwinding coil 21 and guided by guide rods 29 and 30, which are arranged on the left and right side respectively, along the front surface of the cassette housing 11 to form a tape path 12A to up-

the winding coil 22.

The coil 21 is placed in a state where a projecting step portion 24a of the lower flange 24 is loosely inserted into a hole 31 with a large diameter in the lower half 15. Furthermore, ring-shaped teeth 24b are formed on the lower surface of the lower flange 24 around its entire circular circumference. On the upper surface of the lower half 15, teeth 32 are further formed in a ring in positions opposite the teeth 24b. The winding coil 21 is influenced in the direction of the side of the lower half 15 by an arm part 33a of a leaf spring 33, which is mounted on the lower surface of an upper plate on the upper half 14. In the normal state, the teeth 24b will therefore be in engagement with the teeth 32. Consequently, the unwinding spool 21 is under control and prevented from rotating as a result of the engagement between the teeth 24a and 32. The spool 21 will thus not rotate unintentionally while the tape cassette 10 is being manipulated or transported. The magnetic tape 12 is thus protected against entanglement and damage, as there is no slack in the magnetic tape 12 that is wound on the coil 21 and as the magnetic tape 12 is prevented from being unintendedly pulled from the coil 21.

On the inside of the spool hub 25 for the spool 21, an insertion part 25a for the spool drive shaft is arranged. A reel drive shaft for the recording/playback device is introduced here. The inner diameter of the spool hub 25 corresponds to the inner diameter of the spool hub for the unwinding spool in a standard tape cassette. The insertion part 25a for the bobbin drive shaft is open on the side of the above-mentioned hole 31.

Furthermore, a depression 23a is formed in the middle part of the upper surface of the coil 21's upper flange 23. A projection 23b is formed in the center of the depression 23a. One arm portion 33a of the leaf spring 33 presses against the protrusion 23b in a downward direction to influence the coil 21 towards the side of the lower half 15. As discussed in more detail below, the coil 21 is movable upwards and downwards after the tape cassette 10 is placed in the recording/playback apparatus, and this freedom of movement for the coil 21 is relatively large. As the recess 23a is located at the circumference of the protrusion 23b, the tip of the arm portion 33a of the leaf spring 33 will not come into contact with the upper flange 23 of the unwinding coil 21 when the coil 21 is moved up and down.

The winding coil 22 is rotatably arranged, so that a fixed shaft 34 which is arranged embedded in the lower half 15 is introduced into the central hole. in the spool hub 28. A central projection 26a on the flat flange 26 is acted upon by another arm portion 33b of the leaf spring 33 in a downward direction, and the spool 22 is acted upon towards the side of the lower half 15. As the spool hub 28 does not occupy a drive shaft, the outside diameter is d2 of the coil hub 28 smaller than the outer diameter dl of the coil hub 25 for the coil 21. As a result of this feature, i.e. that the outer diameter d2 of the coil hub 28 is smaller than the outer diameter dl of the coil hub 25, the amount of magnetic tape 12 that can be accommodated in the tape cassette 10 larger, compared to a case where the outer diameters d1 and d2 of the spool hubs 25 and 28 are equal. Although the size of the tape cassette 10 is small, recording and playback can therefore be carried out for a relatively long time using said tape cassette 10.

The fixed shaft 34 is screwed onto the lower half 15 with a screw 36 in a threaded part 34b in a state where a projection 35 on the lower half 15 enters a groove 34a, which extends in a diametrical direction in the lower part of the fixed shaft 34, as shown in fig. 4A and 4B. The groove 34a and the projection 35 act as a stopper, when the projection 35 is engaged in the groove 34a, after the fixed shaft 34 has been screwed onto the lower half 15 by means of the screw 36. The screw 36 can thus be screwed into the threaded part 34b and the fixed shaft 34 can be placed in the lower half with great efficiency. As discussed in more detail below, a rotational force from the coil 22 acts on the fixed shaft 34 during recording and playback. But the fixed shaft 34 does not rotate unnecessarily as a result of the above-mentioned interaction between the projection 35 and the groove 34a. Accordingly, since the fixed shaft 34 does not rotate, the screw 36 does not loosen, and the fixed shaft 34 is kept in its original fixed state without becoming unstable. Therefore, the coil 22 is kept in a fixed position at all times and rotates in a stable manner. The magnetic tape 12 can thus be wound up evenly by the coil 22 without the tape 12 being damaged and the coil 22 is in stable engagement with a driving force transmitting mechanism as discussed in more detail below.

A gear part 27a is designed on the outer peripheral part of the lower flange 27 for the coil 22. As shown in fig. IB, 1C, 2 and 3, part of the gear part 27a is exposed through a recessed window 37, which is formed in a portion between the side surface and the bottom surface of the lower half 15. The recessed window 37 has a curved shape on the bottom surface side of the lower half 15.

In connection with the winding coil 22, a brake mechanism is also arranged as shown in fig. 5 and 6. A brake member 38 is supported by rivets or the like. 39a and 39b on the lower half 15. The rivets 39a and 39b are inserted through a pair of holes in the brake member 38 in such a way that they are freely displaceable up and down. The brake member 38 is influenced downwards towards the lower half by spiral springs 40a and 40b, which are arranged around the circumferences of the rivets 39a and 39b respectively to prevent the brake member 38 from sliding upwards. When the brake member 38 is acted upon by the coil springs 40a and 40b and is in its lowered position, a main body portion 38a of the brake member 38 will close an elongated hole 45 which is arranged in the lower half 15 for setting purposes which will be discussed below. A finger part 38b is further located at the same height level as the lower flange 27 and is inserted between nearby teeth of the above-mentioned gear part 27a. The coil 22 is thus locked in the current rotating position, and the magnetic tape 12 which is wound on the coil 22 does not get any slack. The outer peripheral part of the lower flange 27, where the gear part 27a is formed, is further located one step lower than the flange surface on the inner peripheral side.

The brake member 38 is moved upwards as discussed below, and in this raised state the finger 38b goes out of engagement with the gear part 27a and the locking effect on the coil 22 is consequently cancelled. As the brake member 38 works by moving parallel to the axis of the coil 22, the brake member 38 will not collide with and damage the magnetic tape 12 which is wound on the coil 22. The construction of the brake mechanism is thus simple. In addition, the mentioned brake mechanism does not take up much space, which is suitable for reducing the size of the tape cassette 10. As the brake mechanism, including the brake member 38, is arranged in the corner part of the cassette housing 11, it does not take up extra space. It is also advantageous with a view to reducing the size of the tape cassette.

Openings 41 and 42 for receiving load bars and an opening for receiving a pressure roller are arranged in the bottom of the tape cassette 10 on the same side as the cover 13. A positioning hole 44 and the oblong positioning hole 45 are further arranged in the bottom surface of the tape cassette 10 on the left and

right side, near the back. These holes 44 and 45 are formed in recesses 46 and 47, respectively. Furthermore, recesses 48 and 49 are formed in the bottom surface of the tape cassette 10 on the left and right side of the cover 13.

Indentations 50 and 51 are formed on the left and right short sides of the tape cassette 10, as shown in fig. IA and runs essentially from the middle to the back of the cassette.

Projections 5 2 and 53 on the lower half 15 are inserted into recesses (not shown) in the underside of the upper half 14 for mutual positioning of the upper and lower halves 14 and 15 for the tape cassette 10, and the upper and lower halves 14 and 15 are for -bound with screws 54 and 55.

Fig. 7-11 shows a tape cassette adapter 60, which is used when a tape cassette 10 with the above-mentioned construction is to be used in a standard apparatus for recording and/or playback.

The tape cassette adapter 60 has a receiving part 61 for the tape cassette 10 and otherwise has an external shape and size which essentially corresponds to that of the standard tape cassette.

as shown in fig. 3. Consequently, the teeth 24b come out of engagement with the teeth 32, and the coil 21 becomes freely rotatable. The brake member 38 is further pushed upwards against the force exerted by the springs 40a and 40b, by the pin 103 which is introduced into the elongated hole 45. The finger part 38b is raised and the finger part 38b's level becomes different from that of the gear part 27a, so that the finger part goes out of engagement. Consequently, the coil 22 is also released from the locked state and becomes freely rotatable.

When the setting means for the recording/playback apparatus is set to playback, the aforementioned bars 104, 105 and 106 will catch and engage the magnetic tape 12 to extract the magnetic tape 12 and move it to positions indicated by solid lines in fig. 12 . Consequently, the magnetic tape 12 is pulled out of the tape cassette 10 to contact a full width erase head 108. The magnetic tape 12 further comes into contact with a guide roller 109 which is equipped with rotating video heads over a fixed angular range, and the tape comes into contact with an audio control head 110. The magnetic tape 12 is thus guided

in a fixed belt movement path. During recording and playback, the magnetic tape 12 is driven in a state where it is clamped between the pressure roller 107 and a pinch roller 111. A driven gear 112, which is rotated by a reel drive motor (not shown) further engages with the gear portion 27a of the reel 22, and the reel is driven consequently in the tape winding direction.

The full-width erasing head 108, the audio control head 110 and the guide roller 109 are constructed according to the same standard as corresponding parts of a standard apparatus for recording and/or playback, which will be discussed below. Consequently, a signal is recorded and played back from the magnetic tape 12 with a tape pattern and format identical to those obtained by the standard apparatus.

In the following, a case is described where the tape cassette 10 is used in a standard device for recording and/or playback, as shown in fig. 13.

In this case, the tape cassette 10 is placed in the tape cassette adapter 60 to form the above-mentioned fixed tape path in the tape cassette adapter 60. This tape cassette adapter 60 which accommodates the tape cassette 10 is placed in the apparatus for recording and/or playback in the same way as when a standard tape cassette is placed in the appliance.

In order for the tape cassette 10 to be accommodated in the tape cassette adapter 60, the front cover part 16 of the tape cassette 10 is first opened, as indicated by the dashed line in fig. IB. The magnetic tape 12 is then pulled out of the tape cassette 10 in a certain length. In this state, the spool 22 is blocked and cannot rotate. But the coil 21 can be turned when the teeth 24b slide over the teeth 32 against the force exerted by the leaf spring 33. Magnetic tape 12 is thus pulled by the coil 21. In case the coil 21 does not rotate smoothly, the magnetic tape 12 can be pulled off while the coil 21 is pushed upwards with a finger for canceling the tooth engagement between the coil 21 and the teeth 32.

In this condition shown in fig. 9, the tape cassette 10 is placed in the receiving part 61 in the lower half 62, and the magnetic tape 12 which has been pulled out is threaded around the guide bars 80; 81 and 82 to be guided by these rods. The magnetic tape is thus guided in particular by these guide rods 80 and 81, as shown in fig. 9, forming the tape path 12B across the front of the openings 76, 77 and 78, as in a standard tape cassette. The upper half 63 is then placed over the lower half 62 as shown in fig. 10 and the halves 62 and 63 are connected with screws 88-91. As shown in fig. 10 and 11, the tape cassette adapter 60 now occupies the tape cassette 10 in a state where the magnetic tape 12 has been pulled out of the tape cassette 10 and guided in its fixed tape path 12B.

Now the function of the individual parts is described when the tape cassette 10 is taken up in the tape cassette adapter 60.

The tape cassette is inserted from above and placed in the section 61.

In this state, the depressions 46-49 in the bottom of the tape cassette 10 will have contact with the respective projections 67-70 in the lower half 62. The side walls of the tape cassette 10 lie opposite the wall portion 66 of the lower half 62. The hole 44 and the oblong hole 45, which is arranged in the lower half 15 of the tape cassette 10 will fit over respective pins 71 and 72 to get the cassette 10 in the correct position in the receiving part 61. In particular, the pin 72 will pass through the elongated hole 45, as shown in fig. 6, to push the brake member 38 upwards against the action of the coil springs 40a and 40b. The brake member 38 is thus pushed up in the axial direction of the coil 22. In the same manner as discussed above, the finger portion 38b of the brake member 38 will disengage with the gear portion 27a in an upward direction to release the blocked coil 22. At the same time, the drive 74 will enter the extracted window 37 from below to engage with the gear portion 27a. The drive 74 can be constructed so that it performs a slight movement, so that it engages with the gear portion 27a without difficulty. The cover 13 makes contact with a rib portion 83 which is formed along the openings 76 and 77 in the lower half 62 and is held in a state where it covers the openings.

The upper half 63 of the tape cassette adapter 60 is mounted on the lower half 62 in a state where the retracting parts 86 and 87 project into the recesses 50 and 51, respectively, which are arranged on the upper surface of the tape cassette 10. Thus the tape cassette 10 is pushed by the protrusions 67-70 for the lower half 62 and of the inward-extending projections 86 and 87 on the upper half 63. The tape cassette 10 is thus placed with a view to its thickness, so that it does not slide out of the recording part 61. The tape cassette 10 is further placed in the recording part 61 in a state where the upper surface and bottom surface of the tape cassette lie substantially in the same plane as the upper surface and the bottom surface of the tape cassette adapter 60.

Fig. 13 shows a standard device 120 for recording and/or playback. The tape cassette adapter 60 with the inserted tape cassette 10 is placed in the standard apparatus 120 on similar

way a standard cassette is placed there. When the tape cassette adapter 60 is placed in a standard apparatus 120, a winding reel drive shaft 121 is thus introduced into the insertion part 25a for the reel drive shaft in the reel 21 and a winding

spool drive shaft 122 is inserted into the insertion part 64a for the gear structure 64 in the cassette adapter 60. Furthermore, load bars 123 and 124 and a pressure roller 125 will enter the openings 76 and 77 and 78 respectively behind the belt path 12B (cf. fig. 7 and 9). When the adapter is inserted, the coil 21 is further pushed upwards as shown in fig. 3, in the same way as with the compact device 100 for recording and/or playback. Consequently, the blocking of the coil 21 is lifted and the coil 21 is freely rotatable. As explained above, the spool 22 is also released from its locked state and is already freely rotatable when the tape cassette 10 is placed in the tape cassette adapter 60.

When placing the tape cassette, the load bars 123 and 124 will catch and engage the magnetic tape 12 and then extract the magnetic tape 12 from the cassette, the load bars 123 and 124 being moved away from the openings 76 and 77 and reaching the positions indicated by solid lines in fig. 13. Accordingly, the magnetic tape 12, which has been pulled out of the tape cassette adapter 60, will contact the erasing head 126 with full width and with a guide roller 1=7 which is provided with rotating video heads over a certain angular range. The magnetic tape 12 further makes contact with an audio control head 128. Thus, the magnetic tape 12 is placed in the fixed tape movement path.

During recording and playback, the magnetic tape 12 is driven in a state where it is clamped between a pressure roller 129 and a pinch roller 125. The gear structure 64 in the tape cassette adapter 60 is further rotated in a clockwise direction by the reel drive shaft 122 for the reel 22. This rotation of the gear structure 64 is transmitted to the reel 22 via the drive 74 to drive the magnetic tape 12 in the winding direction. Accordingly, the magnetic tape 12 which is fed out of the pressure roller 129 is wound up on the spool 22. The magnetic tape is guided by the guide rods 81 and 82 in the tape cassette adapter 60.

Whether the tape cassette 10 is independently placed in a compact apparatus 100 for recording and/or playback or the tape cassette is placed in a standard apparatus 120 for recording and/or playback when the cassette is in the tape cassette adapter 60, the spool 21 will fit over the drive shaft 101 (121) for the winding coil which is arranged in the recording/playback apparatus, and the coil 21 is driven directly. Thus, the ion accuracy of the coil 21 is great and a very accurate tape feed can be achieved. As the diameter dl of the spool hub 25 in the spool 21 is large, the difference between the maximum and minimum diameter of the roll of wound tape on the spool 21 will be relatively small. Thus, the variation range of the reel 21 rotation speed from start to completion of recording and playback becomes small and the accuracy of the hand movement is improved.

As for the take-up spool 22, this is not placed over the spool drive shaft in any of the cases, where the tape cassette 10 is independently placed in a compact type apparatus 100 or in a standard apparatus 120 by means of the cassette adapter 60. Thus, the amount of tape to be recorded can be increased for a given cassette type, or the size of the cassette housing 11 can be reduced for a given amount of tape. The coil 22 is driven indirectly from the side of the cassette housing 11 via the gear structure 64 and the drive 74. However, as there are no strict requirements for rotational accuracy for the coil 22, no disadvantages arise. As the spool 22 rotates without clearance around the fixed shaft 34, no additional space around the spool is required either, and this helps to reduce the size of the tape cassette.

When the tape cassette 10 is taken out of the recording part of a compact device 100 for recording and/or playback, the spool 21 and the brake member 38 will be moved downwards. Thus, both coil 21 and coil 22 are automatically blocked against rotation. When the tape cassette 10 is removed from the adapter 60 after it has been removed from the recording part of a standard device 120 for recording and/or playback, the brake member 38 will similarly move down to block the reel 22.

Now follows a description of a further embodiment of a tape cassette with reference to fig. 14-17. In figures 14-17, the parts which are similar to corresponding parts in fig. IB, 1C, 2 and 3 are denoted by the same reference number and not discussed in more detail.

A tape cassette 140 is of the same type as the mentioned tape cassette 10, except for the construction in the circumference of the lower flange of the take-up spool 141.

The lower flange 142 of the coil 141 has a flat surface from the inner circumference to the outer circumference and is provided with a gear part 142a in the outer circumferential surface. This gear part 142a engages with the brake member 38 to block the spool 141 so that it cannot rotate, in the same way as with the tape cassette 10.

A gear part 142b is arranged in the lower surface of the lower flange 142. The diameter d3 of this gear part 142b is smaller than the diameter of the lower flange 142 and essentially corresponds to the diameter of the spool hub 28. This diameter d3 is smaller than the diameter of the corresponding gear part 27a in the tape cassette 10 as shown in fig. 3, and has e.g. a value which is approximately half the diameter of the gear portion 27a.

A drive 143, which is axially supported by a pin 144, is arranged on the lower half 15. This drive 143 is placed in a position on the lower side of the lower flange 142. One end of the drive 143 engages with the gear part 142b, while the the other side is exposed in the cut-out window 37 in the lower half 15 as regards a diameter direction of the drive 143. The diameter of this drive 14 3 is substantially equal to the diameter of the above-mentioned gear part 142b.

The tape cassette 140 which has the above-mentioned construction is placed in a tape cassette adapter with an internal design that differs from the adapter's 60 which is shown in fig. 10. Fig. 18 shows the lower half 150 of this tape cartridge adapter. Lower half 150 is identical to lower half .62 which is shown in fig. 7, except for a rotation transmission mechanism 151. A gear structure 152 in said rotation transmission mechanism 151 has a coil insertion hole 152a, where the winding coil drive shaft is inserted, in the inner area, and a gear part 152b formed in the peripheral surface. A drive 153 is axially supported on a pin 154, which is arranged on the lower half, in a state where the drive 153 is engaged with the above-mentioned gear part 152b and the drive 74.

The tape cassette 140 is placed in the tape cassette adapter in a similar way to the above-mentioned tape cassette 10. Fig. 19 shows a state where the tape cassette 140 is placed in the lower half 150 of the adapter. The tape cassette 140 is arranged in the adapter in a state where the drive 143 is engaged with the drive 74. As shown in fig. 13, the adapter that accommodates the tape cassette 140 is placed in a standard apparatus 120 for recording and/or playback. During recording and playback, the gear structure 152 engages with the take-up reel shaft 122 (cf. Fig. 11) and rotates in a clockwise direction.

This rotation of the gear structure, 152 is transferred to the gear part 142b via the drives 153, 74 and 143. The coil 141 thus rotates in a clockwise direction to wind up the magnetic tape 12 around the coil hub 28. Here, the coil hub 28 must be turned at a fixed rotational speed, so that there is not a slack in the magnetic tape 12 which is gradually fed forward when the tape 12 is wound up. Since the diameter d2 of the bobbin hub 28 in the above-mentioned bobbin 141 is small, the value of said fixed rotation speed becomes a high value. However, in the present embodiment of the invention, the diameter d3 of the gear part 142b for the coil 141 is small. Consequently, the drives 153, 74 and 143, which have a small diameter and are necessary for turning the coil 141 with the above-mentioned determined rotation speed, must only be turned at significantly lower rotation speeds than in the first mentioned embodiment of the invention. Therefore, the rotary transmission mechanism can be operated stably and the system is ensured a long service life.

As the diameter d3 of the gear part 142b for the coil 141 is small, the coil 141 can also be turned at a high rotational speed without the rotation transmission mechanism being exposed to too great a load. The diameter of the spool hub 28

in the winding coil 141 can thus be further reduced and the tape cassette 140 is consequently able to wind up and accommodate a larger amount of tape.

Also, the drive 153 is arranged in the tape cassette adapter, in contrast to the drive 143 which is placed in the tape cassette 140. The spool 141 thus rotates in the same direction as the spool shaft 122 and the spool 141 winds the tape in the same way as the standard winding spool in a standard tape cassette. This also applies to the tape cassette 10 mentioned above.

When the tape cassette 140 is placed in a compact apparatus 100 for recording and/or playback, the drive 143 engages with the drive drive 112 of the compact apparatus 100. In this case, the drive drive 112 rotates in the opposite direction to what is the case when compact device 100 is supplied with a tape cassette 10. But the winding spool 141 is turned in a clockwise direction as when using a tape cassette adapter, via the drive 143.

In each of the mentioned embodiments according to the invention, instead of arranging the gear part in the circumferential side of the lower flange 27 on the spool 22 in the tape cassette 10 and arranging a rotation-transmitting disc instead of the drive 143 in the tape cassette 140, a rubber roller can be used in rota- the transmission mechanism in the tape cartridge adapters in the first two embodiments set forth above. In this case, the rotation is transferred to the take-up spool 22 in the tape cassette 10 and to the rotation transfer disc in the tape cassette 140 by friction occurring between them.

The gear part in the circumference of the lower flange of the coil 22 in the tape cassette 10 can also be designed as a bevel gear part. In this case, a bevel wheel arranged on a horizontal shaft of the adapter 60 or on the side of the apparatus will enter through an opening in the bottom surface of the tape cassette for the slotted window 37 arranged in the tape cassette 10. The bevel wheel will engage with said bevel wheel portion of the lower flange in a state where the bevel wheel crosses the lower flange 27 in a perpendicular manner.

The present invention is not limited to the mentioned embodiments, but allows various variations and modifications within the scope of the invention as stated in the subsequent claims.

Claims (10)

1. Tape cassette (10) for use in an apparatus (100, 120) for recording and/or playback, which apparatus comprises a feed reel drive shaft (101, 121) and a take-up reel drive (112), the tape cassette (10) comprising a cassette housing (11 ), a feed side coil (21) with flange (24) and hub (25), and a winding side coil (22) with flange member (27) and a second hub (28) with center hole, arranged in the cassette housing (11) for winding of a tape, where the winding side spool's flange member (27) has an engagement member (27a) which is placed laterally in relation to the cassette housing (11), and where the feed side spool's hub (25) has coupling members (25a) formed in its bottom center, the engagement member (27a) directly engages with the take-up reel drive member (112) and the coupling members (25a) engage with the feed reel drive shaft (101, 121) when the tape cassette (10) is placed in the apparatus (100, 120), characterized in that the feed side the spool's hub (25) and flange (24) respectively have diameters that are relatively larger than diam the take-up side coil hub (28) and flange member (27) ethers, and that a fixed shaft (34) is mounted on a base plate (15) in the cassette housing (11) to receive the center hole in the take-up side coil hub (28) and rotatably support the take-up side coil (22). 2. Tape cassette as set forth in claim 1, characterized in that said flange member (27) on the winding-side coil (22) comprises a coil flange (27) which transfers rotational energy in an outer peripheral part (27a) of the coil, and that the cartridge housing ( 11) has an opening (37) in a part which corresponds to said coil flange. 3. Tape cassette as stated in claim 2, characterized in that the coil flange (27) has a gear part (27a) for transferring rotational energy at an outer peripheral part thereof. 4. Tape cassette as stated in claim 1, characterized in that said flange member on the winding lens side coil (22) comprises an upper coil flange (26) and a lower coil flange (27), and that the lower coil flange (27) is designed so that rotational energy is transferred in an outer peripheral part of this (27a). 5. Tape cassette as stated in claim 4, characterized in that it also comprises a brake member (38), which is movable in a direction parallel to the axis of rotation of the spools, i.e. upwards and downwards, as the brake member establishes contact with one of the upper and lower spool flanges (26, 27) for braking the rotation of the winding side coil (22), and influencing means (40a, 40b) which force the braking means (38) downwards for contact with said one coil flange, and where the braking means (38) is arranged to be displaced upwards to be separated from a peripheral part of said one coil flange for canceling the braking effect, the braking member and the influencing member being arranged in the cassette housing. 6. Tape cassette as specified in claim 5; characterized in that said one coil flange on the winding-side coil has a gear part (27a) for transferring rotational energy at an outer peripheral part, and that the braking means (38) performs braking of the winding-side coil (22) by engaging with said gear part. 7. Tape cassette as specified in claim 5, characterized in that the cassette housing (11) has a hole (45) formed at a place in the lower surface which corresponds to the position of the brake member (38), and that the brake member can be displaced upwards by a pin-shaped member (72, 103) which is introduced through said hole, said pin-shaped member acting against the force from the influencing member, so that the braking effect is cancelled. 8. Tape cassette as stated in claim 7, where the device for recording and/or playback is a device (100) which is used exclusively for said tape cassette, and has a recording part, where the tape cassette is placed and which receiving part comprises said pin-shaped member (103), characterized in that the brake member (38) is arranged to be raised by the pin-shaped member which is introduced through said hole (45) in the cassette housing when the tape cassette is placed in said absorbing party. 9. Tape cassette as stated in claim 7, where the device for recording and/or playback is a standard device (120) for recording and/or playback, which is normally supplied with a standard tape cassette, the tape cassette housing (11) being smaller than standard - the tape cassette as the tape cassette (10) is placed in the standard device in a. tape cassette adapter (60) with an external shape and size which essentially corresponds to the shape and size of said standard tape cassette, the tape cassette adapter having said pin-shaped member (72) at a receiving part (61) thereof, characterized in that the brake member (38) is arranged to be raised by the pin-shaped member which is inserted through the hole (45) in the cassette housing when the tape cassette is placed in the receiving part of the adapter. 10. Tape cassette as stated in claim 2, characterized in that the fixed shaft (34) has a non-circular protrusion (34a) at its lower end, that the cassette housing has a non-circular projection (35) at a mounting part for the fixed shaft for fitting into and engaging the non-circular recess, and that the fixed shaft is attached to the cassette housing with a screw (36) in a state where the non-circular recess is positioned over the non-circular projection.