JPH0120503B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a tape drive device used in a tape recorder.

In order to make tape running more stable in a tape recorder, a so-called double capstan type is used, in which a first capstan and a second capstan are placed on the tape winding side and the tape supply side, respectively, sandwiching the magnetic head. Are known.
However, with this method, if the rotational speeds of both capstans do not match completely, the tape feeding speed will deviate. For example, if the rotational speed of the first capstan is faster than the second capstan, both The tape may be subject to excessive tension between the capstans, damaging the tape, or causing slippage between the tape and the capstan, resulting in poor sound quality. On the other hand, if the rotational speed of the second capstan is faster, various problems may occur, such as the tape becoming loose due to insufficient tension of the tape.

This invention was made based on the above circumstances, and its purpose is to allow the tape to run between both capstans while applying appropriate tension, thereby preventing damage to the tape or slipping between the capstan and the tape. An object of the present invention is to provide a tape drive device that can prevent such problems.

The first embodiment of this invention will be described below with reference to FIGS. 1 and 2.
This will be explained based on the diagram. In the figure, 1 is a motor, and this motor 1 is fixed to a base 2.
Further, 3 is an erasing magnetic head, 4 is a recording/reproducing magnetic head, and A is a tape. The base 2 includes magnetic heads 3 and 4 in the middle of a tape running system extending between a supply reel and a take-up reel (not shown).
A first capstan 5 and a second capstan of the same diameter are placed on the winding side and the supply side of the tape, respectively.
A capstan 6 is rotatably supported.
7 and 8 are bearings, and 9... are bearing metals. Also,
Pinch rollers 10 and 11 are pressed against the capstans 5 and 6, respectively.

Further, a flywheel 12 is fixed to the first capstan 5. This flywheel 12
is formed with a large diameter part 12a and a small diameter part 12b, and the small diameter part 12b and the motor 1
A belt 14 for power transmission is stretched between the pulley 13 attached to the output shaft of the motor. On the other hand, the second
The capstan 6 is provided with a torque transmission mechanism 15. The torque transmission mechanism 15 includes a drive-side rotating body 16 that is rotatably supported by a second capstan 6, and a second capstan 6 that is provided facing away from the rotating body 16 with a slight gap.
and a driven side rotating body 17 fixed to. The drive-side rotating body 16 is provided with permanent magnets 16a whose polarity is alternately changed along the circumferential direction.
... is arranged, and the driven side rotating body 17
A magnetic body 17a is disposed at a position facing the permanent magnets 16a. Further, the diameter D ₂ of the drive-side rotating body 16 is larger than the diameter D ₁ of the large diameter portion 12 a of the flywheel 12 .
A power transmission belt 18 is stretched between the large diameter portion 12a and the drive-side rotating body 16. That is, in this embodiment, the large diameter portion 1
2a, the belt 18, and the outer periphery of the rotating body 16 constitute a deceleration means defined as a means for decelerating and transmitting the rotation of the first capstan.

Next, the operation of the device of the above embodiment will be explained. When the motor 1 is rotated and the flywheel 12 is rotated via the belt 14, the first capstan 5 is rotationally driven. This rotational force is then transmitted to the drive side rotating body 16 of the torque transmission mechanism 15 via the belt 18, and the rotating body 16 rotates. Incidentally, since the diameter D ₂ of the drive-side rotor 16 is larger than the diameter D ₁ of the flywheel 12, the drive-side rotor 16 has a lower speed than the first capstan 5, that is, the speed of D ₁ /D ₂ is lower than that of the first capstan 5. It will rotate at the number of revolutions. When the driving side rotating body 16 rotates, the driven side rotating body 17 and the driving side rotating body 16
The driven rotating body 17 rotates due to the magnetic force acting between the two capstans and the second capstan 6, so that the second capstan 6 rotates at a slightly lower speed than the first capstan 5.

However, when tape A is run with capstans 5 and 6 having different rotational speeds as described above, the second
A force corresponding to this speed difference is applied to the capstan 6 to force it to rotate by the tape A. However, since the driving-side rotating body 16 and the driven-side rotating body 17 are rotating together through magnetic force, the driven-side rotating body 17 is not affected by the forced rotational force caused by the tape applied to the driven-side rotating body 17. The rotation of the side rotating body 17 is allowed, and the driven side rotating body 1
7 rotates at a slightly higher speed than the drive-side rotating body 16, so that the rotational speeds of both capstans 5 and 6 match. In other words, the tape A is subjected to resistance between the capstans 5 and 6 according to the difference in rotation between the rotating bodies 16 and 17, and tension is applied to the tape A.

In this way, according to the above embodiment, both capstans 5 and 6 rotate at the same speed while the tape is running, and an appropriate tension is applied to the tape A due to the magnetic resistance caused by the speed difference between the rotating bodies 16 and 17. Since tape A can be given a
This prevents excessive tension from being applied to the capstans 5, 6 and the tape A from slipping, or from stretching the tape A and damaging the tape.

Note that FIG. 3 shows a second embodiment of the present invention, and the torque transmission mechanism 15 in this case is constructed as follows. That is, the second capstan 6 rotatably supports the foil 20,
This wheel 20 is rotated together with the flywheel 12 by the belt 18, and a driving side rotating body 21 is fixed to the wheel 20, and the driven side rotating body 22 is spaced apart and facing the driving side rotating body 21. is fixed to the second capstan 6. That is, in this embodiment, the large diameter portion 12a of the flywheel 12, the belt 18, and the foil 20 constitute a deceleration means defined as a device that decelerates and transmits the rotation of the first capstan. . The driving side rotating body 21 and the driven side rotating body 2
2 is accommodated in a fluid chamber 23, and this fluid chamber 23 is filled with a fluid 24 having an appropriate viscosity. Note that 25 is a seal for obtaining liquid tightness.
Therefore, in the case of this embodiment, the driven side rotating body 22
is driven to rotate like a fluid joint through the resistance of the fluid 24 when the drive-side rotating body 21 rotates. Due to this fluid resistance, it is possible to tolerate the speed difference between the two rotating bodies 21 and 22, and to apply tension to the tape A, as in the first embodiment. Since the other configurations are the same as those in the first embodiment, corresponding parts are given the same reference numerals and explanations will be omitted.

As described with reference to the above embodiments, the present invention includes a first capstan disposed on the winding side of the tape running system, a motor that rotationally drives the first capstan, and a motor that decelerates the rotation of the first capstan. a torque transmission mechanism comprising: a deceleration transmission means for transmitting torque; a driving-side rotary body rotated by the deceleration transmission means; and a driven-side rotary body that rotates with the rotation of the driving-side rotary body while allowing slippage; The second capstan is disposed on the supply side of the tape running system and is integrally driven to rotate in the same direction as the first capstan as the driven rotating body rotates.

According to the tape drive device having the above configuration, it is possible to run the tape while applying rotational driving force in the same direction to the first capstan and the second capstan, while making the apparent rotational speeds of both capstans match each other. , and the difference in the rotational speed of the second capstan, which is reduced in speed with respect to the first capstan, is applied to the tape by applying appropriate tension to the tape by a torque transmission mechanism that allows relative slippage between the driving side rotary body and the driven side rotary body. Since the tape is absorbed in a state where it is given a magnetic head, it is possible to take advantage of the excellent performance of the double capstan system, such as improved modulation noise and better contact between the tape and the magnetic head. At the same time, excessive tension is not applied to the tape, and the tape can always be run with an appropriate tension.

Therefore, while fully utilizing the advantages of the double capstan system, it is possible to prevent problems such as deterioration of sound quality caused by damage to the tape or relative slippage between the tape and the capstan, and to improve the performance of audio equipment such as tape recorders. performance can be significantly improved.

[Brief explanation of drawings]

1 and 2 show a first embodiment of the present invention, FIG. 1 is a plan view schematically showing a tape drive device, FIG. 2 is a longitudinal sectional view of the same device, and FIG. FIG. 3 is a longitudinal cross-sectional view of a tape drive device showing a second embodiment of the present invention. 1...Motor, 3, 4...Magnetic head, 5...
1st capstan, 6... 2nd capstan, 1
5... Torque transmission mechanism, 16, 21... Driving side rotating body, 17, 22... Drive side rotating body, 24... Fluid, A... Tape.

Claims (1)

[Scope of Claims] 1. A first capstan disposed on the winding side of the tape running system, a motor that rotationally drives the first capstan, and a deceleration transmission means that decelerates and transmits the rotation of the first capstan. and a torque transmission mechanism comprising a driving-side rotating body rotated by the deceleration transmission means and a driven-side rotating body that rotates in conjunction with the rotation of the driving-side rotating body while allowing slip, and a supply side of the tape running system. The first rotor is arranged at
A tape drive device comprising: a second capstan that is rotationally driven in the same direction as the rotation direction of the capstan. 2. The tape drive device according to claim 1, wherein the driven rotating body is driven by the driving rotating body through a magnetic force generated between the driven rotating body and the driving rotating body. 3. The tape drive device according to claim 1, wherein the driven rotating body is driven by the driving rotating body through resistance of a fluid interposed between the driven rotating body and the driving rotating body.