DE3225210C2 - - Google Patents

Description

The invention relates to a magnetic tape device comprising: one connected to a magnetic head, the magnetic head between a rest position and an operating position moving actuating element, the actuating element ment against the force of a return spring in the operating position-moving, motor-driven cam be, an the actuator in the operating position locking by means of an electromagnet device and a direction reversal device for Switching the tape running direction.

Such a magnetic tape device is from JP-56-77 937 known. The curves work in this known device disc directly on the actuating element for the magnet head. If the device is moved while the magnetic head is moving or turned off, the magnetic head can be installed in an instabi len intermediate state remain. An unstable two The condition can also occur if during Movement of the magnetic head causes the device to fast forward or rewind or the user tries to to stop ejecting. In such circumstances, had to the user will wait until the press process for  the head was closed because of forced operation Could damage the magnetic head and the like.

The object of the invention is therefore a magnetic tape device of the type mentioned above so that even with one Switching or switching off the device during movement tion of the magnetic head is ensured that the magnet head is returned to a stable position.

To solve the problem, the magnetic tape is mentioned Art according to the invention that the Cam a switching element of the direction reversal device drives. The switching element takes one on the one hand, the actuating element via a movable control element of the actuator from the rest position in the operating position with. On the other hand, it switches the Tape running direction over a lever element, which with a locking area of the switching element together works. The locking device also acts on the Control element so that the actuator at Ent excitation of the electromagnet regardless of the position of the Cam free to return to the rest position given is.

The cam thus actuates the actuating element for the magnetic head not directly, but indirectly via the switching element for reversing the direction of travel and the Control, which is via the locking device is under the influence of the electromagnet. When excited The electromagnet becomes the control element over the latches tion device in engagement with the switching element brought and the actuator from its rest be taken into its operating position. Becomes however, the magnet in an intermediate position between the rest position and the operating position of the actuator  excitation element, so the entrainment takes place between the switching element and the switching element ver loren, and the actuator returns under the effect of Return spring to its stable rest position, and regardless of the position of the cam. In the electromagnet is de-energized when the device is switched off or fast forward or Return is switched.

The actuating element preferably has control means for the control of the lever element. You can get here through that the tape running direction even during movement of the Actuator in its preset position remains.

A preferred embodiment is as follows explained in more detail with reference to the drawing. Show it:

FIG. 1a to 6a views illustrating the effect of the parts, relating to the pressing of a head,

FIG. 1b to 6b are views relating to the parts that relate to the Unschaltwirkung for the tape running direction,

Fig. 7 to 10 views with respect to the switching effect for the tape running direction substantially according to Figs. 2b to 5b, and

FIGS. 11 and 12 views has returned from a lever element in a state in which the actuating element position in the output.

In the drawing is the embodiment of the invention designed so that in addition to switching the Belt running direction causes a head to be pressed. In the drawing, the terms "above" refer "below", "right", "left" and the like on the shown Location of parts.

First, the elements will be described with reference to FIGS. 1a to 6a, which relate to the pressing of the head. The reference numerals 1 and 1 'relate to Kapstans, which are each held on a mounting frame, not shown; the reference numeral 2 relates to a coaxial to the capstan 1 'arranged gear which rotates together with a motor, not shown; the reference numeral 3 is an intermediate wheel held on the fastening frame with a toothing which, with the exception of a section 4 cut away, is in meshing engagement with the toothed wheel 2 ; the reference numeral 5 is an integrally formed on the intermediate wheel 3 cam with a stepped area 6 at the end of its cam track. The reference sign 7 relates to a switching element with slots 9 and 9 ', engage in the guide pins 8 and 8 ', which are arranged on the mounting frame, so that the switching element can make a movement to the right and left. The reference numeral 10 relates to a provided on the switching element 7 role (or a pin) for a grip with the cam 5 and the reference numeral 11 a spring that biases the switching element 7 to the left before. The tensile force of the spring 11 causes the roller 10 to come into contact with the cam plate 5 . If Figure 1a, the intermediate so is Fig. 3, that it is out of engagement with the gear 2, is the roller 10 in contact with the stepped portion 6 of the cam plate 5 so that the force of the roller 10 move to the left wants to take the idler gear to a rotation in the counterclockwise direction in a position for engagement with the gear 2 . Against this force, a stop element 12 holds the intermediate wheel 3 in the position shown in FIG. 1a. The stop element 12 is pivotally held by the guide pin 8 'and is positioned due to the tensile force of a spring 14 in the position shown in Fig. 1a, while a release coil 13 held on the mounting frame is de-energized to touch a projection 15 formed on the intermediate wheel 3 and thereby keep the idler gear 3 at rest in the position shown.

The reference numeral 16 relates to an actuating element with a stroke limiting hole 18 and elongated holes 18 'and 18 '', engage in the guide pins 17 , 17 and 17 '', so that the actuating element 16 can move up and down within the limited stroke distance . The reference sign 19 relates to a ge on the actuator 16 holding head, and the reference numerals 20 and 20 'relate to springs that bias the actuator 16 upwards. When the lowermost end of the stroke limiting hole 18 is in contact with the guide pin 17 , the head 19 is in the released state. The reference numeral 21 relates to a slightly elongated hole in the actuating element and the reference numeral 22 is a control element which is pivotally held and is used with its support point 23 in the hole 21 for upward and downward movement. The control element 22 has an inclined surface 24 formed on its upper right side and a downwardly inclined surface 25 and an upwardly inclined surface 26 , both of which are formed on the upper left side of the control element. The reference numeral 27 relates to a spring which biases the supported point 23 of the control element 22 upwards in the direction of the actuating element 16 . The spring force of the spring 27 is greater than the spring forces of the springs 20 and 20 'so that when the control element 22 is in the upper position shown in Fig. 1a and 2a and of course when it is pressed down according to Fig. 3a , The supported point 23 remains in contact with the uppermost end of the hole 21 until the uppermost end of the stroke limiting hole 18 comes into contact with the guide pin 17 so that the actuating element 16 cannot move further down.

Reference numeral 28 relates to a sector element which is pivotally held on the fastening frame. The sector element 28 has an engagement area 30 which is in engagement with a slot at the left end of the switching element 7 , so that when the engagement area 30 is moved to the right and left as a result of a movement of the switching element 7, a projection 31 formed on the sector element 28 , which is in contact with the inclined surface 24 of the control element 22 , makes an upward and downward movement. The reference numeral 32 is a locking element which is pivotally held with its support point 33 on the fastening frame. The locking element 32 has a projection 34 which is in contact with the inclined surfaces 25 and 26 , as well as an engagement part 35 which is formed at its upper region. Reference numeral 36 relates to a holding element, 37 a hole formed at the left-hand end of the holding element 36 for engagement with the engaging part 35 of the locking element 38, a spring which engages the part 35 to the lower right end of the hole 37 on the right-hand side with respect to the holding element 36 prestresses, 39 a movable core provided at the right-hand end of the holding element 36 , which cooperates with a holding coil 40 held on the fastening frame, and 41 a spring which prestresses the holding element 36 to the right in order to move the movable core 39 against the holding coil 40 . The spring force of the spring 38 is greater than that of the spring 41 , so that when the movable core 39 is attracted by the holding coil 40 as shown in FIG. 5a and the projection 34 of the locking element 32 in contact with the upwardly inclined surface 26 of the control element 22 to prevent upward movement of the control element 22 , the spring force of the spring 38 maintains the locked state, while when the holding coil 40 is de-energized, the locking element 32 rotates counterclockwise against the spring 41 , thereby releasing the locked state according to FIG. 6a .

Reference numeral 42 relates to a arranged on the mounting frame stop which limits the rotary movement of the control member 22 in the clockwise direction, and the reference numeral 43 a also provided on the mounting frame boundary plate, which limits the rotary movement of the control element 22 in counterclockwise direction to a rotational movement of the control member in a counterclockwise direction prevent subsequent to the locking member 32 even after the inclined surface 24 of the control member 22 comes out of contact with the projection 31 on the sector member 28 while the control member 22 moves from the position shown in Fig. 3a to the position shown in Fig. 6a, which would be connected with difficulty that the upwardly inclined surface 26 comes out of contact with the projection 34 of the locking element 32 .

With reference to FIGS. 1b to 6b and FIGS. 7 to 12, the elements which bring about the change in the tape running direction are discussed below. The reference numeral 44 be a Umschaltnockenführungselement which is pivotally held on the mounting frame and has a V-shaped cam guide hole 46 which extends substantially on both sides of a support point 45 , and carries at its lowermost end a projection 47 . When the switching cam guide element 44 swings out around the support point 45 , the projection 47 moves to the left and right in order to move a partially shown channel switching plate 49 with a recess 48 into which the projection engages, thereby changing the tape running direction and the channel. The reference numeral 50 relates to a lever element with a support point 51 , which engages movably in a hole 52 formed in the switching element 7 and is thereby pivotally held. The lever member 50 carries an urging pin 53 at its left end which engages in the cam guide hole 46 . The reference numeral 54 relates to a spring that pulls the support point 51 down and the reference numeral 55 a spring that pulls the pin 53 to the left. Hole 52 has a generally J-shaped configuration with a sink area 56 at its right-hand lowermost end. The incidence area 56 is designed such that the support point 51 comes to lie at the same height level as the support point 45 when the support point 51 lies in the incidence area according to FIGS . 7 to 11, while the left section of the hole 52 carries the support point 51 on a holds higher position. Numeral 58 is a stepped portion integrally formed on the actuator 16 near the hole 52 . The stepped region 58 has an upper horizontal edge which is substantially aligned with the lower edge of the hole 52 when the actuating element 16 is in the highest position according to FIGS . 1b and 2b (in the position for releasing the head 19 ). , And a sloping edge that extends from the right end of the upper horizontal edge to the far right end of the actuating element 16 to substantially the same height level as the bottom of the incident area 56 .

The device designed as described above works as follows. As far as the pressing of the head is concerned, the device is initially found in the position shown in FIG. 1 in the idle state. At this time, the support point 51 of the lever element 50 is on the left side of the incidence region 56 of the hole 52 .

If e.g. B. a cassette is inserted in this state, the release coil 13 is energized to rotate the stop element 12 in the counterclockwise direction and since by disengaging from the projection 15 . Then the roller 10 presses against the stepped region 6 due to the tensile force of the spring 11 and moves this stepped region to the left, which brings about a rotation of the cam plate 5 in the counterclockwise direction. Due to the rotation of the cam 5 , the intermediate gear 3 integrally connected to it undergoes rotation in the same direction, so that it comes in meshing contact with the gear 2 which is rotated clockwise by the motor. Due to the left-hand movement of the switching element 7 as a result of the left-hand movement of the roller 10 , the projection 31 of the sector element 28 moves upward, so that it comes up from the area of the right side surface of the control element 22 to the inclined surface 24 and thus the control element moves in the clockwise direction can turn. The control element 22 , the locking element 32 and the holding element 36 thus move clockwise and to the right due to the tensile force of the spring 41 , as a result of which the movable core 39 is moved against the holding coil 40 and is attracted and held by the latter (see FIG. 2a). . Although at this point the support point 51 of the lever element 50 has arrived just above the area of incidence 56 , it does not fall into it, since it lies on the stepped area 58 of the actuating element (cf. FIG. 2b).

The meshing engagement with the gear 2 intermediate wheel 3 moves sequentially in the same direction, so that the cam 5 strikes the roller 10 in such a way that the switching element 7 experiences a movement to the right. As a result, the projection 31 on the sector element 28 moves downward, as a result of which the control element 22 is urged to a position below the inclined surface 24 . If the control element 22 is pressed down, the actuating element 16 together with the control element 22 is pressed down until the uppermost end of the stroke limiting hole 18 comes into contact with the guide pin 17 , while the locking element 32 against the tensile force of the spring 38th rotates in the counterclockwise direction, since its projection 34 is acted upon by the downwardly inclined surface 25 of the control element 22 (cf. FIG. 3a). At this time, the support point 51 of the lever element 50 is located to the left of the incidence area 56 (cf. FIG. 4a).

Even after the actuating element 16 has reached the lowermost end (namely the position in which the head 19 is pressed), the control element 22 continues to be pressed continuously until the roller 10 reaches the highest position of the cam plate 5 . At this time, the support point 23 moves downward in the hole 21 against the tensile force of the spring 27 , while the locking element 32 rotates clockwise due to the tensile force of the spring 38 , since its projection 34 comes from the area of the downwardly inclined surface 25 is (see Fig. 4a). Here, the support point 51 of the lever element 50 is located at essentially the extreme left end of the hole 52 (cf. FIG. 4a).

When the roller 10 disc over the highest position of the curves 5 passes, the idler gear is 3, after it has taken a position at which its cut-away portion 4 which faces the gear wheel 2, except meshing engagement, and enters the stop element 12, which due to the tensile force of the spring 14 after de-energization of the release coil has returned to the stopping position, in engagement with the projection 15 to hold the idler gear 3 in said position. On the other hand, the switching element 7 moves due to the tensile force of the spring 11 to the left until the roller 10 comes into contact with the stepped region 6 , which causes a movement of the projection 31 on the sector element 28 upwards. The control element 22 , which no longer acts on the downward pressure through the projection 31 , moves upwards due to the tensile force of the spring 27 until the upwardly inclined surface 26 comes into contact with the projection 34 of the locking element 32 . This locked state, in which the upwardly inclined surface 26 is in contact with the projection 34 , is maintained by the holding force of the holding coil 40 and the tensile force of the spring 38 . In this locked state, the projection 23 on the control element 22 is locked somewhat at a distance from the uppermost end of the hole 21 , so that the tensile force of the spring 27 can act effectively on the actuating element 16 in order to hold it securely in the lowest position (ie the Position in which the head 19 is pressed), cf. Fig. 5a. The locked state is then maintained over the entire playing time of the tape. At this point in time, the support point 51 of the lever element 50 is in essentially the same position as in FIG. 1b (cf. FIG. 5b).

In the course of the transition from FIG. 2a to FIG. 5a and in the locked state according to FIG. 5a, a user only needs to de-energize the holding coil 40 in order to trigger a process for releasing the head. Then the holding force of the holding coil 40 ends on the holding element 36 and the locking element 32 , so that the tensile force of the springs 20 and 20 ', which bias the control element 22 upwards via the actuating element 16 , exceeds the tensile force of the spring 41 , which is the control element 22 biases on the locking element 32 in a clockwise direction. The control element 22 with rotation in the counterclockwise direction in such a way that the projection 31 on the sector element 28 is avoided, then passes freely from the projection 31st At the same time, the upward sloping surface 26 which urges the projection 34 of the locking member 32 to the left so that the locking member 32 makes a counterclockwise rotation except out of contact with the projection 34 which causes an upward movement until the bottom end of the stroke limiting hole 18 comes into contact with the guide pin 17 (ie until the head 19 is released). When the holding coil 40 is substantially de-energized in the state shown in FIGS . 3a and 3b, the device changes its position to the state shown in FIGS . 6a and 6b. And when the motor continues to rotate, the idler gear 3 comes to a standstill after the continuous rotation from the position shown in FIG. 6a to the position shown in FIG. 1a.

During the transition from Fig. 2a in Fig. 5a and in the ver locked state according to FIG. 5a returns the actuating element 16 also in case of interruption of the power supply immediately in the position for releasing the head 19 back, as the holding coil 40 is de-energized due to this interruption, .

Switching the tape running direction is described below. If in the tape game position shown in Fig. 5a, the release coil 13 is energized, the stop element 12 comes free from the projection 15 and the cam 5 rotates accordingly, so that in the same way as in Fig. 2a, the intermediate gear 3 in engagement with the gear 2 is coming. On the other hand, since the actuating element 16 assumes the lowest position (the position for pressing the head 19 ), the support point 51 of the lever element 50 falls according to the left-hand movement of the switching element 7 into the incident area 56 due to the tensile force of the spring 54 (see FIG. 7).

During the right-hand movement of the switching element 7 due to the rotation of the intermediate wheel 3 from this state, the lever element 50 , whose support point 51 is held by the locking region 57 of the hole 52 , moves to the right against the tensile force of the spring 55 . As a result, the urging pin 53 comes into an upper region of the cam guide hole 46 in order to press the right end of the changeover cam guide element 44 and to rotate it clockwise. As a result, the channel switching plate 49 moves to the left through the projection 47 , which causes a change in the tape running direction and the channel (see FIGS. 8 and 9).

When the idler gear 3 has completed one revolution and the projection 15 engages the stop member 12 , the lever member 50 moves to the left together with the switching member 7 so that the pin 53 is in the position corresponding to the extreme left end of the upper portion of the Cam guide hole 46 comes to a standstill (see. Fig. 10).

In the transition from Fig. 8 to Fig. 9, ie during the action of the switching cam guide element 44 , the incidence area 56 , even if the actuating element 16 has returned from the lowest position to the uppermost position, to the right of the oblique edge of the stepped area 58 , and the stepped area does not enter the incidence area 56 , so that the lever element 50 is held in the position in which its support point is blocked by the locking area 57 (see FIG. 11).

When the operating member 16 from the lowermost position to the uppermost position at the completion of the work of Umschaltnockenführungselementes 44 that is returning from the position shown in Fig. 10, the stepped portion 58 is in a position for entering the incident area 56 where the stepped portion 58 lifts the support point 51 and brings it out of the incidence area 56 (see FIG. 12) so that the lever element 50 can return to the position shown in FIG. 5b.

When the release coil 13 is energized from the position shown in Fig. 10 position out again, the actuation enters pin 53, since the Umschaltnockenführungselement 44 which occupies in Fig. Position and 10 shown is not the position according to Fig. 5b, in the lower portion of the cam guide hole 46 , which results in a rotation of the element 44 in the counterclockwise direction. This causes the channel switching plate 49 to move to the right, which causes an opposite change in the tape running direction.

Although the control member 22 is pivotally supported for upward and downward movement relative to the operating member 16 in the above-described embodiment, it need not be movable upward or downward. Both the locked te state in the transition from Fig. 2a to Fig. 5a and the locked state shown in Fig. 5a are retained in the aforementioned embodiment only by a holding coil 40 . However, two independent coils can also be provided. Furthermore, although the device according to the above-mentioned embodiment is so laid out that it performs the pressing operation of the head in addition to changing the tape running direction, the invention is not limited to such an arrangement. Rather, the invention can be modified and modified in various ways.

As described, the actuation according to the invention element for moving and pressing the head out of the transferring relationship to the cam itself during of the shifting and pressing process for the head will. Due to this circumstance, the activity reverses element when the power supply is interrupted stopping the motor halfway through the head pushing the actuator through the curves disc or when performing an actuation process by the user halfway through another operator process immediately into its stable position by the De-excitation of the electromagnetic coil.

Even if the effect of the actuator on half Ways of effect of the switching element for the change the tape running direction is deleted, the Umschaltele ment continue to do its job. This ver prevents the switching element in an unstable position halfway through the switchover process to a standstill  comes so that the tape running direction always in safer and is changed more completely.

Claims (2)

1. Magnetic tape device, comprising
a with a magnetic head (19) connected to the magnetic head (19) between a rest position and an operating position, moving actuating element (16),
a the actuating element ( 16 ) against the force of a return spring ( 20 , 20 ') move into the operating position de, motor-driven cam ( 5 ),
a locking the actuating element ( 16 ) in the operating position by means of an electromagnet ( 39 , 40 ) de locking device ( 32 , 36 ) and
a direction of reversal device ( 7 , 44 , 50 ) for switching the direction of tape travel, characterized in that
that the cam ( 5 ) drives a switching element ( 7 ) of the direction of rotation reversal device ( 7 , 44 , 50 ), which on the one hand takes the actuating element ( 16 ) via a movable control element ( 22 ) of the actuating element ( 16 ) from the rest position into the operating position and on the other hand via a lever element ( 50 ), which cooperates with a locking region ( 57 ) of the switching element ( 7 ), switches the tape running direction, and
that the locking device ( 32 , 36 ) acts on the control element ( 22 ) so that the actuating element ( 16 ) is released for de-energizing the electromagnet ( 39 , 40 ) regardless of the position of the cam disc ( 5 ) for the return to the rest position . 2. Magnetic tape device according to claim 1, characterized in that the actuating element ( 16 ) has control means ( 58 ) for controlling the lever element ( 50 ).