KR920008564Y1 - Tape recorder - Google Patents

Abstract

No content.

Description

Tape recorder

1 is a plan view showing a stationary state of the tape recorder device of the present invention in a state where a related component for loading and ejecting a tape cassette is removed.

2 to 4 are explanatory views of the play operation.

5 is an exploded perspective view showing the installation configuration of the magnetic head to the head mounting plate.

6 is an explanatory diagram showing a relationship between a detection lever and a rocking arm.

7 is a block diagram of a high speed circuit transmission mechanism.

8 is an exploded perspective view of the sub-board portion.

9 and 10 are explanatory views of the operation of the high speed rotation transmission mechanism.

11 is an exploded perspective view of related parts for loading and ejecting a tape cassette.

12 and 13 are plan views illustrating the loading and ejecting operations of the tape cassette.

14 to 17 are side views of the same.

18 and 19 are diagrams illustrating eject operation.

* Explanation of symbols for the main parts of the drawings

5: Tape Drive Motor 6a: One Reel Support

6b: Reel rest on the other side 19: Head mounting plate

46: electromagnet for play 47: electromagnet for rewind

48: electromagnet for quick delivery 53: pivot lever

55: slide lever 58: swing lever

61: second cam gear (cam gear) 63: head extrusion spring

65: pressing body 75: tape running direction detection member

79: rotating member 85: slide plate

87: connection spring 88: high speed rotation switching lever

90: switching gear for high speed rotation 101: electromagnet for eject

119: slide piece 124: eject lever

129: load 131: inverted spring

132: slider 133: rock

138: eject plate

The present invention relates to a tape recorder device in which a plurality of mechanisms such as a head moving mechanism and an eject mechanism are operated by a tape driving motor.

Conventionally, Japanese Unexamined Patent Publication No. 60-229265 discloses a tape recorder that operates an ejection mechanism using a rotational force of a tape drive motor, and a tape recorder device of operating a head moving mechanism using a rotational force of a tape drive motor. Japanese Patent Laid-Open No. 61-74163 is known, respectively.

By the way, if both of the ejection mechanism and the head movement mechanism are to be operated by using the rotational force of the tape drive motor, simply think of the combination of the mechanisms of both conventional tape recorder devices as described above. Combining these mechanisms makes the configuration extremely complicated.

The present invention has been made in view of the above circumstances, and a high-speed rotation for selecting the head moving mechanism and the left and right reel supports at high speed by using the rotational force of the tape drive motor by a simpler configuration than the conventional mechanisms. It is an object of the present invention to provide a tape recorder apparatus for operating the delivery mechanism.

In order to achieve the above object, the tape recorder apparatus of the present invention has a cam portion and a cam gear pivotally driven by a tape driving motor, a rocking lever that swings in conjunction with the cam gear, a play electromagnet, and the play. A head moving mechanism which is engaged with the swing lever by the electromagnet and driven by the swing lever, each electromagnet for fast forwarding and rewinding, and an electromagnet for fast forwarding or rewinding, usually in a neutral position. A tape running direction detecting member moving in the reverse direction, a rotating member supported by the detecting member to be rotated freely, displaced according to the position of the detecting member, driven by the head moving mechanism, and rotating in the direction corresponding to the displacement position; High speed that transfers the rotational force of the motor to one or the other of the reel supports in conjunction with this rotating member at high speed It is characterized by having a rotation transmission mechanism.

In the tape recorder device of the present invention, the rotational force of the tape driving motor is transmitted to the head moving mechanism through the cam gear and the swinging lever to operate the head moving mechanism, and the rotational force of the tape driving motor is the head moving mechanism and the rotating mechanism. The high speed rotation transmission mechanism operates by being transmitted to the high speed rotation transmission mechanism through the member. An embodiment of the present invention is described below with reference to the drawings. FIG. 1 is a plan view of the tape recorder device of the present invention in a state in which the related parts for loading and ejecting a tape cassette are removed. In this figure, (1) is a substrate and on one side (left side in the drawing). It is comprised by providing the elongate sub board | substrate 4 in the upper surface of the other side (right side in drawing) of the main board 3 which has the protruding wall 2. A tape driving motor 5 is disposed on the upper surface of the protruding wall 2, and a pair of reel supports 6a and 6b and capstan shafts 7a and 7b are disposed on the upper surface of the main board 3, respectively. .

The rotational force of the tape drive motor 5 is transmitted to each reel support 6a, 6b via the gearwheel rotation transmission mechanism 8, and each capstan shaft 7a, through a belt rotation transmission mechanism (not shown). 7b) respectively. The gear type rotary transmission mechanism 8 includes a first gear 9 fixed to a rotating shaft of a tape drive motor 5 and a second gear 10 in which the first gear 9 and the teeth mesh with each other. The third gear 11 which rotates integrally with the same axis as the second gear 10, the fourth gear 12 in which the third gear 11 and the teeth mesh, and the fourth gear 12 and the teeth The fifth gear 13 which engages, the 6th gear 14 which rotates integrally with the same axis as this 5th gear 13, and the 7th gear 15 which teeth and the gear | engagement mesh with, The eighth gear 16 integrally rotating on the same axis as the seventh gear 15, the low speed reel gears 17a and 17b integrally rotating on the same axis as the reel supports 6a and 6b, and the high speed reel. It has gears 18a and 18b.

Then, during the play operation, the low-speed rotational switching gear 28, which will be described later, by the low-speed rotational reel gear 17a on the side of the eighth gear 16 and the reel support 6a on one side (below in FIG. 1). The low speed rotation reel gear 17b on the side of the reel support 6b of the sixth gear 14 and the other side (upper side in FIG. 1) is connected via the low speed rotation switching gear 28. The teeth are alternately switched in the engaged state so that each reel support 6a, 6b rotates at a low speed (normal speed). In addition, at the time of the fast forward (FF) operation or the rewind (REW) operation, the high speed rotation reel gear 18a on the side of the seventh gear 15 and one reel support 6a will be described later. 90 is a state in which the gear is engaged and the high speed reel gear 18b on the other side of the reel support 6b on the other side of the fifth gear 15 is engaged with the teeth through the high speed rotation switching gear 90. The reel bases 6a and 6b are rotated at high speed by alternately switching states. The head mounting plate 19 is mounted on the upper surface of the main board 3 so as to be movable in the directions of arrows A and B (left and right directions in FIG. 1). On the upper end side of the head mounting plate 19 (the right end side in FIG. 1), a tape guide 20 made of synthetic resin is provided by screws 21 and 21, as shown in FIGS. On the upper surface of the tape guide 20, the magnetic head 23 is provided by screws 24 and 24 via one leaf spring 22. As shown in FIG. The magnetic head 23 contacts the tape 115b of the tape cassette 115 described later as the head mounting plate 19 moves in the direction of arrow A to reach the play position during the play operation. The head mounting plate 19 is elastically supported in the direction in which the magnetic head 23 is separated from the tape, that is, the arrow B direction, by the head return spring 25 as in FIG. The leaf spring 22 has a V-shaped bent portion 22a at approximately the middle in the longitudinal direction as shown in FIG. 5, and has inverted V-shaped curved portions 22b and 22c at both ends in the longitudinal direction. Long holes 26 are drilled in the bent portions 22b and 22c at both ends, and screws 24 and 24 are inserted into the long holes 26 and 26, respectively. By adjusting the body part of these screws 24 and 24, it is possible to perform the Esmus (inclination) adjustment of the magnetic head 24. As shown in FIG.

By providing the leaf springs 22 having the above-described configuration, it is possible to adjust both sides of the magnetic head 23 at the same height position. On the lower side of the head mounting plate 19 (left end in FIG. 1), as shown in FIG. 1, the switching gear 28 for low speed rotation is rotatable through the support member 27, and the head mounting plate ( 19) is supported to be movable in the direction orthogonal to the moving direction (the arrow C and D direction in FIG. 1). The support member 27 is made of synthetic resin and integrally protrudes the single axis cylindrical portion 27b on the central upper surface of the plate-shaped main body 27a, and on both sides of the outer peripheral surface of the cylindrical portion 27b (up and down in FIG. 1). Each side piece 27c, 27d is integrally protruded from the side part, and the missing piece 27e is integrally protruded from the one side member (left part in FIG. 1) of the outer peripheral surface of the cylindrical part 27b. And the cylindrical part 27b is the 1st long hole 29a of the head mounting plate 19, and the front end of each piece 27c, 27d is the 2nd, 3rd long hole 29b of the head mounting plate 19. And 29c) so as to be movable. When a part of the head mounting plate 19 is held in the state where the main body 27a and the retaining piece 27e are sandwiched, the fall prevention piece 27e is formed on the upper surface side of the head mounting plate 19 together with the respective pieces 27c and 27d. It is located in the guide hole 31 of the moving plate 30. The moving plate 30 is mounted on the upper surface of the main board 3 so as to be movable in a direction orthogonal to the moving direction of the head mounting plate 19 (arrows C and D directions). In the engaging hole 32 provided in the movable plate 30, the engaging pin 34 which protrudes eccentrically on the upper surface of the engagement gear 33 is engaged.

The toothing gear 33 is provided by providing two toothing parts 33a and 33b by 180 degree shifting in the circumferential direction, and is supported by the axis | shaft so that the lower surface of the main board 33 can rotate. The gear 33 engages teeth with the first cam gear 35. The first cam gear 35 is the same as the fourth gear 12 of the gear type rotary transmission mechanism 8. The tooth is engaged with the small diameter gear 36 which can rotate integrally with the shaft. Then, the moving plate 30 moves in the direction of the arrow D as the toothing gear 33 is rotated approximately 180 ° clockwise in the initial state (state of FIG. 1), and the toothing gear 33 is clockwise again. The moving plate 30 moves in the direction of arrow C by rotating approximately 180 degrees. In the initial state (state of FIG. 1), the tip of each piece 27c of the support member 27 moves as the moving plate 30 moves in the direction of arrow A to reach the play position. The low-speed rotational switching gear 28 integrally with the support member 27 moves in the direction of arrow C by slidingly engaging the inclined edge portion 31b of the guide hole 31 of the plate 30 from the inclined edge portion 31b to the guide edge portion 31a. Thus, the gear 28 meshes with the sixth gear 14 of the cogwheel rotational transmission mechanism 8 and the low speed reel gear 17b on the other side of the reel support 6b. Moreover, when the moving plate 30 is in the position moved to the arrow D direction, as the head mounting plate 19 moves toward the play position, the tip of each piece 27d of the support member 27 moves to the moving plate 30. The low-speed rotational switching gear 28 moves in the direction of the arrow D integrally with the support member 27 while slidingly engaging from the inclined edge portion 31d of the guide hole 31 to the guide edge portion 31c. 28 is engaged with the eighth gear 16 of the gear type rotary transmission mechanism 8 and the reel gear 17a for low speed rotation on one side of the reel support 6a. The pinch rollers 38a and 38b are rotatably provided on the upper surface of the main board 3 corresponding to the capstan shafts 7a and 7b via pinch roller arms 37a and 37b as shown in FIG. Each pinch roller arm 37a, 37b is rotatably supported on the upper surface of the main board 3 by the installation shafts 39a, 39b.

One end of the rod spring 41 is caught by the spring engaging portion 40a of one pinch roller arm 37a, and the other end of the rod spring 41 has a spring coefficient 40b of the other pinch roller arm 37b. ) Is engaged to the long hole 42 of the movable plate 30. The bar spring 41 has the bent parts 41a and 41b for abutting on both ends, and has the roller engagement bent part 41c in the middle part generally. Then, by engaging the annular engaging holes 43a of the flat roller 43 with the roller engaging bent portion 41c as shown in FIG. 5, the roller 43 is approximately the middle of the rod spring 41. It is kept rotatable. The roller 43 is slidably joined to the vertical guide surface 44 integrally provided on the tape guide 20. The movement of the rod spring 41 in the direction of arrows C and D is facilitated by the action of the roller 43. The rod spring 41 moves integrally with the moving plate 30 and the head mounting plate 19, respectively. . One guide piece 45a in which the contacting bent portion 41a of one end of the bar spring 41 protrudes from the head mounting plate 19 when the moving plate 30 moves in one direction (arrow C direction). Touches. Moreover, the other guide piece in which the contacting bending part 41b of the other end side of the rod spring 41 protrudes to the head mounting plate 19 at the time of moving to the other direction (arrow D direction) of the moving plate 30. Abuts at 45b.

When the moving plate 30 moves in one direction (arrow C direction) when the head mounting plate 19 is moved in the direction of arrow A, the pinch roller 38a is acted on one side by the action of the bar spring 41. Spaced apart from the capstan shaft 7a, the other pinch roller 38b is pressed against the other capstan shaft 7b (state of FIG. 4). In addition, when the head mounting plate 19 is in the play position and the moving plate 30 moves in the other direction (arrow D direction), one pinch roller 38a acts as one capstan shaft ( 7a) is pressed and the other pinch roller 38b is spaced apart from the other capstan shaft 7b. On the upper surface of the sub-board 4 disposed at intervals above the main board 3, the electromagnet 47 for rewinding and the electromagnet 48 for fast forwarding are provided as shown in FIG. have. The electromagnet 46 for play is "on" when the tape cassette 115 is loaded in a predetermined state, and has adsorption portions 46a and 46b on both sides. The adsorption part 49a of the 1st amateur 49 is attached to the adsorption part 46a of one side, and the adsorption part 50a of the 2nd amateur 50 is respectively attached to the adsorption part 46b of the other side. Is adsorbed. The first armature 49 has a flat plate shape, and its middle part is a suction part 49a, and its lower end is supported by the mounting shaft 51 so as to be rotatable to the sub-board 4.

The first armature 49 is elastically supported on the suction side (clockwise in FIG. 1) by the return spring 52 (see FIG. 8). The distal end of the first amateur 49 abuts against the distal end of the pivot lever 53 made of synthetic resin. This pivoting lever 53 has an engagement recess 54 in its approximately middle portion in its longitudinal direction and the proximal end 53a is rotatable to one end of the slide lever 55 as in FIGS. 2 and 3. Further, the slide lever 55 is integrally slidable in a direction orthogonal to the moving direction of the head mounting plate 19 (arrows C and D directions).

As shown in FIG. 1, the slide lever 55 is slidably mounted on the upper surface of the sub substrate 4 in the directions of arrows C and D. As shown in FIG. As the first amateur 49 is attracted to the electromagnet 46 for play, one end of the pull arm 56 is engaged with the engaging recess 54 of the pivoting lever 53 as shown in FIG. ) This pull arm 56 is rotatably supported by the mounting shaft 39a of the other pinch roller arm 37b so that the middle part of the pull arm 56 can rotate. The other end of the pull arm 56 is rotatably connected to one end of the swing lever 58.

The swing lever 58 is rotatably supported on the upper surface of the sub-substrate 3 by its mounting shaft 59. The other end of the swing lever 58 is slidably engaged with the cam 62 of the second cam gear 61 through the cam roller 60 rotatably installed therein as shown in FIGS. 2 and 3. Lost

The 2nd cam gear 61 has the engagement part 61a in one place. The second cam gear 61 is meshed with the small-diameter gear 36. Then, in response to the rotation of the second cam gear 61 in the counterclockwise direction, the swing lever 58 rotates clockwise by the action of the cam 62, and the pull arm 56 in the clockwise direction. The slide lever 55 pulls and slides in one direction (arrow C direction) through the rotation lever 53 in which the engaging piece 56a of one end of this pull arm 56 engages with the engaging recess. According to the slide of the slide lever 55, the head mounting plate 19 is pushed and moved in one direction (arrow A direction) through the head extrusion spring 63. As shown in FIG. The head extrusion spring 63 has one end caught by the spring catching portion 55a of the other end of the slide lever 55 and the other end of the head mounting plate 19, as in the second, third, seven, nine, and ten degrees. It is caught by the spring coefficient 65a of the press body 65 which presses the 1st to-be-pressed part 64 of this. When the swing lever 58 rotates due to the rotation of the cam 62 different from the regeneration operation, the slide lever 55 moves in the direction of the arrow C during the first middle. The pressing body 65 which rotates through the slide lever 55 and the head compression spring 63 resists the force of returning the head mounting plate 19 to the head return spring 25 so that the head mounting plate is arrow A. FIG. Press in the direction.

That is, the head moving mechanism is configured as the head mounting plate 19, the rotation lever 53, the slide lever 55, the head extrusion spring 63, and the pressing body 65.

The second armature 50 has an adsorbed portion 50a at one end of the main body 66 whose plane is generally L-shaped, and also protrudes the engaging piece 67 at an approximately middle portion of the main body 66. You have to install.

It is rotatably supported on the upper surface of the sub board | substrate 4 by the installation shaft 68 in the substantially intermediate part of the main body 66. As shown in FIG. The second armature 50 is elastically supported on the suction side (clockwise in FIG. 1) by the return spring 69. As shown in FIG. Then, when the slide lever 55 slices in one direction (arrow C direction) and reaches a predetermined position, the engaging piece 67 of the second armature 50 engages with the engaging hole 70. When the second armature 50 is attracted to the electromagnet 46 for play in the fit state, the slide lever 55 is kept in a state of sliding in one direction (state of FIG. 3). The slide lever 55 is elastically supported in the other direction (arrow D direction) by the head extrusion spring 63.

Therefore, when the electromagnet 46 for play becomes " off ", the slide lever 55 slides back in the other direction by the elastic support force of the head compression spring 63. FIG. The rewinding electromagnet 47 and the fast-forwarding electromagnet 48 have adsorption portions 47a and 48a on one side, respectively, and the third and fourth armatures 71 and 72 of each of the adsorption portions 47a and 48a. Suction part 71a, 72b adsorb | sucks. The third and seventh amateurs 71 and 72 have a substantially L-shaped plane, and end portions at one side thereof are rotatable on the upper surface of the sub-board 4 by the installation shafts 73 and 74, respectively. Supported. As for the 3rd and 4th amateurs 71 and 72, the intermediate part of the one side side becomes the to-be-adsorbed part 71a, 72a. When the third armature 71 is attracted to the returning electromagnet 47, the third arm 71 rotates counterclockwise so that the pressing end 71b of the other side of the third arm 71 fits the projection 75a of one side of the tape traveling direction detecting member 75. Touch and press this. The fourth armature 72 is rotated in the clockwise direction while being adsorbed by the fast-forwarding electromagnet 48 so that the pressing end portion 72b of the other side is attached to the other projection 75b of the tape traveling direction detecting member 72. Press it against it. When the fourth armature 72 is adsorbed by the quick-delivering electromagnet 48, it rotates in a clockwise direction so that the pressing end 72b of the other side is applied to the other projection 75b of the tape traveling direction detecting member 75. Press against it.

As shown in FIG. 8, the tape running direction detecting member 75 is rotatably supported at the installation side 76 of the sub-board 4 at the same time as the installation hole 75c of the intermediate portion is rotatably formed at both ends thereof. 75a and 75b are protruded, respectively, and a substantially triangular engaging hole 77 is drilled in one end. The tape traveling direction detecting member 75 presses one of the projections 75a as the pressing end 71b of the third amateur 71, so that the tape running direction detecting member 75 is clockwise and the other projection 75b is fourth. Since it presses as the pressing end 72b of the armature 72, it rotates counterclockwise, respectively.

The tape running direction detection member 75 is elastically supported in the neutral position by the return spring 78. The rotation member 79 is rotatably supported by the tape running direction detection member 75.

As shown in FIG. 8, the pivot member 79 has a support shaft 80 at the substantially center of the upper surface, and also has the pins 81a and 81b at both ends, and has a fitting piece 82 on one side of the lower surface. have. The rotation member 79 is rotatably supported by the tape travel direction detection member 75 by engaging the support shaft 80 in a rotatable manner with the engagement hole 77 of the tape travel direction detection member 75. have.

Therefore, the rotation member 79 is displaced in the same direction as the head mounting plate 19 (arrows A and B directions) in accordance with the rotational displacement of the tape running direction detection member 75. Then, when the rotation member 79 is displaced in one direction (right in FIG. 7) in accordance with the clockwise rotational displacement of the tape running direction detection member 75, the blood press of one side (right in the drawing) The pressing portion (see Fig. 8) 83a of one side (right side in the drawing) of the slide lever 55 abuts on the portion 81a and rotates in accordance with the movement in the arrow C direction of the slide lever 55. The member 79 rotates counterclockwise. In addition, when the rotation member 79 is displaced to the other side (left in FIG. 7) in accordance with the rotational displacement in the counterclockwise direction of the tape running direction detection member 75, The pressing member 83b of the other side (left side in the drawing) of the slide lever 55 abuts against the pressed portion 81b, and the rotating member 79 moves in accordance with the movement of the slide lever 55 in the arrow C direction. Rotate clockwise.

The rotation member 79 is elastically supported in the neutral position by the return spring 84 (see FIG. 8). The engagement pin 82 of the rotation member 79 is engaged with the engagement hole 86 of the slide plate 85 slidably mounted to the main board 3 in the direction of arrows C and D. Then, the slide plate 85 slides in the directions of arrows C and D as the pivot member 79 rotates. The slide plate 85 is connected to the proximal end of the high speed rotation switching lever 88 via a coupling spring 87.

This high speed rotation switching lever 88 is supported by the mounting shaft 89 on the lower surface of the main board 3 so as to be rotatable, as shown in FIG. 7. At the distal end of the high speed rotation switching lever 88, a high speed rotation switching gear 90 is rotatably supported by the shaft. Then, as the slide plate 85 slides in the direction of arrow C, the high speed rotation switching lever 88 rotates in the counterclockwise direction, and the high speed rotation switching gear 90 is the seventh of the gear type rotary transmission mechanism 8. Cogs are engaged with the gear 15 and the reel gear 18a for high speed rotation on one side of the reel support 6a, and the one of the reel supports 6a rotates at high speed. In addition, as the slide plate 85 slides in the direction of the arrow D, the high speed rotation switching lever 88 rotates clockwise so that the high speed rotation switching gear 90 is the fifth gear of the gear type rotary transmission mechanism 8 ( 13) and the teeth engage with the high speed reel gear 18b on the other side of the reel support 6b, and the other reel support 6b rotates at high speed.

The high speed rotation switching lever 88 does not mesh with any of the gears of the high speed rotation switching gear 90 in a neutral state (state of FIG. 7) except during the fast forwarding and rewinding operation. As described above, the high speed rotation transmission mechanism is constituted by the slide plate 85, the connection spring 87, the high speed rotation switching lever 88, and the high speed rotation switching gear 90. The movement stroke in the direction of arrow A of the head mounting plate 19 is changed when the high speed rotation switching lever 88 is in the neutral position and when it is rotated clockwise and counterclockwise.

That is, the stopper protrusion 91 protrudes from the high speed rotation switching lever 88, and this stopper protrusion 91 is engaged with the engagement hole 92 provided by the head mounting plate 19. When the high speed rotation switching lever 88 is in the neutral state, the moving limit position in the direction of the arrow A of the head mounting plate 19 is the center recess 92a of the engaging hole 92 of the head mounting plate 19. ) Is fitted to the stopper protrusion 91, whereby the magnetic head 23 is restricted to a position where the tape cassette contacts the tape, and the moving stroke of the head mounting plate 19 at this time becomes S. Further, when the high speed rotation lever 88 is rotated clockwise or counterclockwise, the second or third abutting portions 92b and 92c of the engaging hole 92 of the head mounting plate 19 are added. By contacting the stopper projection 91, the magnetic head 23 is restricted to a position slightly separated from the tape of the tape cassette, and the moving stroke of the head mounting plate 19 at this time becomes S ₁ (< S).

The lower surface of the gear 33 is provided with a cam 93 having abutting ends 93a and 93b at positions 180 degrees apart as shown in FIGS. 4 and 6. The abutted portion 94s of one end of the first trigger arm 94 alternatively abuts on these abutting ends 93a and 93b, and is supported by the main board 3 so as to be rotatable. .

The inclined surface 94b at the other end of the first trigger arm 94 is slidably engaged with the pin 97 at one end of the second trigger arm 96.

The second trigger arm 96 is rotatably supported by the main board 3 by its mounting shaft 98. The engaging piece 100a of the movable plate 100 is engaged with the engaging tool 99 at the other end of the second trigger arm 96. The movable plate 100 is connected to the plunger 101a of the ejector electromagnet 101 by sliding in the same direction as the head mounting plate 19 (arrows A and B directions).

The ejector electromagnet 101 is provided on the upper surface of the protruding wall 2 of the main board 3. When the ejector electromagnet 101 is turned "on", the second trigger arm 96 rotates counterclockwise as the movable plate 100 moves in the direction of arrow B integrally with the plunger 101a. Accordingly, the first trigger arm 94 rotates in the counterclockwise direction so that the abutted portion 94a escapes from the abutment portions 93a and 93b of the cam 93 of the toothed gear 33. Rotation restriction to the fish 33 is released. The movable plate 100 is elastically supported in the arrow A direction by the return spring 102.

As shown in FIGS. 4 and 6, the spring 104 is disposed between the spring catching portion 94c of the first trigger arm 94 and the spring catching portion 103a of the first stage of the detector lever 103. ) Has been refurbished. The detector lever 103 is provided on the main board 3 so as to be slidable in the same direction as the head mounting plate 19 (arrows A and B directions). The detector lever 103 has a first locking piece 103b and a second locking piece 103c at its other end and at approximately the middle portion thereof. The detector lever 103 is elastically supported in the arrow A direction by the spring 104. The first engaging stone piece 103b of the detector lever 103 is in contact with the one end engaging part 50b of the second amateur 50. When the electromagnet 46 for play is " off ", the detector lever 103 slides in the direction of the arrow A as the elastic bearing force of the spring 104 so that the second catching stone piece 103b is one end of the rocking arm 105. Abuts against the projection 105a. In addition, when the electromagnet 46 for play is turned "on", the second armature 50 rotates clockwise, so that the detector lever 103 slides in the direction of arrow B against the elastic bearing force of the spring 104, The locking piece 103c of 2 does not press the protrusion 105a of the rocking arm 105. As shown in FIG.

The rocking arm 105 is supported by the installation shaft 106 so that the intermediate part may be rotatable. Friction between the reel supports 6a, 6b and the corresponding reel gears 17a, 17b (18a, 18b) on the abutting surfaces 105b, 105c at both ends of the rocking arm 105; The pins 108a, 108b protruding from the friction plates 107a, 107b of the clutch mechanism abut. The cam sliding joint 105d protrudes from the rocking arm 105. The cam sliding engaging portion 105d is slidably joined to the first cam 109 and the second cam 110 provided in the first cam gear 35. And while the reel support 6a or 6b is rotating, the friction plate 107a or 107b receives a rotational force so that the pins 108a, 108b abut the contact surface 105b or 105c of the rocking arm 105. The rocking arm 105 is rotated and elastically supported in the counterclockwise direction so that the cam sliding joint 105d is pressed against the first cam 109. Then, when the load reaches the tape end and the load of the reel support 6a or 6b is greater than or equal to a predetermined value, the rotational force of the friction plate 107a or 107b is lost due to the stop of the reel support 6a or 6b. And the rotational force in the counterclockwise direction with respect to the rocking arm 105 is not acted. Thus, after the rocking arm 105 is rotated clockwise by the action of the first cam 19, the rocking arm 105 is rotated clockwise by the action of the second cam 110 and then the second cam 110 is rotated clockwise. The rocking arm 105 rotates clockwise again under the action of In response to the clockwise rotation of the rocking arm 105, the projection 105a presses the second inclined surface 94d on one end of the first trigger arm 94. It rotates counterclockwise, and the to-be-contacted part 94a comes out of the contact end part 93a or 93b of the binder gear 33. As shown in FIG.

A rotating plate 111 is provided on the upper surface of the main board 3 as shown in FIGS. 11 to 17. In this rotating plate 111, mounting holes 112a and 112b on both sides of the front end portion thereof are rotatably fitted to mounting shafts 113a and 113b on both sides of the front wall 3a of the main board 3. For this reason, the rotating plate 111 can be rotated in the up-down direction using the installation shafts 113a and 113b as a point. The cassette holder 114 is arrange | positioned under the rotating plate 111. As shown in FIG.

The cassette holder 114 holds the tape cassette 115 and has tape cassette insertion and exit ports 114a at both rear ends thereof. Engaging protrusions 116a and 116b which are formed by bending on both sides of the upper surface of the cassette holder 114 and protruded are rotatably engaged with the engaging holes 117a and 117b provided on the rear end side of the upper surface of the pivoting plate 111. Moreover, the fitting projections 118a and 118b which are bent and formed in one side surface of the cassette holder 114, and are provided so that the inclined holes 120a and 120b of the slide piece 119 are movably fitted are made. The slide piece 119 is slidably mounted on the inner side surface of the one side wall 3b of the main board 3 in the same direction as the moving plate 30 (arrow C, D direction), and the arrow is caused by the return spring 121. It is elastically supported in the D direction. First, second, third, and fourth engagement protrusions 122a, 122b, 122c, and 122d are formed in the slide piece 119 by bending. These first to fourth engagement protrusions 122a to 122d are the first, second, third and fourth engagement holes 123a, 123b, and 123c provided in the side wall 3b of the main board 3 to be installed. And (123d) are movably engaged.

On the outer side surface of the first side wall 3b of the main board 3 facing the slide piece 119, the eject lever 124 is movably mounted in the same direction as the slide piece 119, and the return spring 125 is provided. It is elastically supported in the arrow D direction. The eject lever 124 has first and second engagement holes 126a and 126b and engagement protrusions 127. The first engagement protrusion 122a of the slide piece 119 is attached to the first engagement hole 126a by the third engagement protrusion of the slide piece 119 at the second engagement hole 126b. In addition, the engaging projection 127 is fastened to the fifth engaging hole 123e of the one side wall 3b of the main board 3, respectively. Thus, the slide piece 119 and the eject lever 124 can be connected to each other without using a fixing member such as a piece.

The ejection lever 124 is connected to an approximately intermediate portion of the spring support plate 130 through a rod 129 having one end rotatably installed in the installation hole 128 of the upper end thereof. One end of the spring support plate 130 is supported on the upper surface of the rotation plate 111 by the mounting shaft 13a so as to be rotatable. The other end of the spring support plate 130 is connected to the slider 132 through the reverse spring 131. The slider 132 moves in the same direction (arrow C, D direction) as the moving plate 30 along the engagement hole 111a of the rotating plate 111. The slider 132 engages with the reel hole 115a of the tape cassette 115 loaded in the cassette holder 114. When the slider 132 slides in the direction of arrow C and reaches a predetermined position in accordance with the charging of the tape cassette 115, the elastic force of the reversing spring 131 is reversed, and the spring support plate 130 is also reversely rotated. The lock plate 133 is provided below the rotation plate 111 so as to be rotatable in the same axis as the spring support plate 130. The lock plate 133 is elastically supported in the clockwise direction as the return spring 134. The locking plate 133 is provided with a locking claw 136 that is engaged with the lock 135 of the slide piece 119, and the locking claw 136 contacts with the hook 135 so that the arrow of the slide piece 119 is caught. The amount of movement in the D direction is regulated. In the fitting holes 137a and 137b provided at the upper and lower edges of the eject lever 124, the fitting pieces 139a and 139b provided at the upper and lower ends of the eject plate 138 are rotated by the insertion operation from above. It is fitted as possible. The eject plate 138 is slidably connected to the other end of the movable plate 100 so that its intermediate plate slidably slides in the direction of arrows C and D with respect to the movable plate 100, but the movable plate 100 The fitting pieces 139a and 139b are rotated in accordance with the movements in the arrows A and B directions. The engaging end 141 of the other end of the swing lever 58 is engaged with the hook 140 at the tip of the eject plate 138 so as to be locked and released.

That is, as the movable plate 100 moves in the direction of arrow B by " on " of the electromagnet 101 for ejecting, the eject plate 138 rotates in the clockwise direction so that the hook 140 is the swing lever 58. Hang on the fitting end 141 of.

The ejection mechanism is constituted by the slide piece 119, the eject lever 124, the rod 129, the reverse spring 131, the slider 132, the lock plate 133, and the eject plate 138.

On the upper surface of the main board 3, as shown in FIG. 1, a rotating body 142 is rotatably provided by the mounting shaft 143. As shown in FIG. The rotating body 142 has a roller sliding portion 142a and a pressing portion 142b, and is supported on the roller sliding portion 142a by a first roller 144 that is rotatably supported on the inner surface of the slide piece 119. ) Is sliding. And as the slide piece 119 moves to the arrow C direction, this rotating body 142 rotates clockwise as the 1st roller 144 slip-bonds to the roller sliding part 142a of the rotating body 142, The pressing portion 142b abuts against the second blood pressing portion 145 of the head mounting plate 19 to forcibly move the head mounting plate 19 in the arrow B direction.

Therefore, if the ejector electromagnet 101 or the like is broken, the eject lever 124 is moved in the direction of arrow C by manual operation, and the slide piece 119 moves in the direction of arrow C together with the head mounting plate 19. Since the arrow moves in the direction B, ejection can be performed even as a manual operation. The second roller 146 is provided on the same axis as the first roller 114, and the second roller 146 is slidably bonded to the inner side surface of the first side wall 3a of the main board 3. On the upper surface of the main board 3, inclined squeezed pieces 147a and 147b are protruded by bending. When the head mounting plate 19 is moved in the direction of arrow A, a portion of the head mounting plate 19 comes into contact with the pressing pieces 147a and 147b. 3) It is prevented from being pushed to the side. As shown in FIG. 4, a pair of engaging projections 148a and 148b are protrudingly provided on the outer gear 33 in the outer peripheral side as shown in FIG. And, when the trigger arm 94 of 1 does not fully return clockwise and the abutted portion 94a does not contact the abutting end 93a or 93b, the abutted portion 94a The rotation of the binder gear 33 is reliably prevented by contacting the locking projection 148a or 148b. The change operation body 150a of the slide type head channel change switch 150 is connected to the moving plate 30 through the spring 149, and the change operation body 150a moves according to the movement of the moving plate 30. Thus, the channel of the magnetic head 23 is switched. 12 and 13, reference numeral 151 denotes a set pressing spring which is a leaf spring provided on the pivoting plate 111 to press the tape cassette 115 down to the main board 3 side.

Next, the loading operation of the tape cassette will be described.

1, 12, 14, and 16 show a stationary state. That is, in the stationary state, as shown in FIG. 12, the slider 132 moves in the direction of arrow D by the elastic supporting force of the reversing spring 131, and the spring support plate 130 is inverted with the lock plate 133. It is rotated clockwise by its elastic bearing force. In addition, since the nail claw 136 of the lock plate 133 is engaged with the hook 135 of the slide piece 119 as shown in Figs. 12 and 14, the slide piece 119 is the return spring 121. The movement in the direction of the arrow D is prevented against the elastic bearing force and the state is maintained in the state of FIG. In addition, since the engaging claw 136 of the lock plate 133 is engaged with the upper edge of the slide piece 119 as shown in FIG. 12, the clock plate of the rotating plate 111 with the lock plate 133 in the clockwise direction. Rotation is prevented so that the pivoting plate 111 is maintained in the same state as in FIG. 16 so that the fitting protrusions 118a and 118b of the cassette holder 114 are inclined to the inclined holes 120a and 120b of the slide piece 119. And the cassette holder 114 is held in the raised position as shown in FIG. In addition, the engaging piece 111b bent at the end of one side wall of the rotating plate 111 is connected to the one side edge portion 152a of the sixth engaging hole 152 of the eject lever 124 as shown in FIG. While sliding and engaging, the eject lever 124 is prevented from moving in the direction of arrow D against the inertia bearing force of the return spring 125, and the eject lever 124 is maintained in the state of FIG. In this state, when the tape cassette 115 is inserted in the direction of arrow C from the cassette insertion hole 114a of the cassette holder 114, the slider 132 is inserted into the reel hole 115a of the tape cassette 115 as shown in FIG. Catches up. After this state, the tape cassette 115 is pushed again in the direction of arrow C. With this, the slider 132 moves in the direction of arrow C against the elastic bearing force of the reverse spring 131. When the tape cassette 115 reaches the predetermined position in the direction of arrow C, the tape cassette 115 is inverted to the elastic support force of the reversing spring 131 and the slider 132 is used as the elastic support force as shown in FIG. The arrow is dragged to the limit position in the C direction. As the slider 132 moves in the direction of the arrow C, a part of the slider 132 abuts against a part of the lock plate 133 so that the lock plate 133 is opposed to the elastic bearing force of the return spring 134. It rotates counterclockwise in FIG. By the rotation of the lock plate 133 in the counterclockwise direction, the locking claw 136 is pulled out of the hook 135 of the slide piece 119, so that the slide piece 119 has the elasticity of the return spring 121. As a bearing force, it moves to the arrow D direction, and it will be in the state like FIG. In addition, since the locking claw 136 is released from the upper edge of the slide piece 119 by the rotation of the lock plate 133 in the counterclockwise direction, the pivot plate 111 is integrally formed with the lock plate 133 and the spring is not shown. It rotates in the clockwise direction in FIG. 14 as the elastic bearing force of to bring it to the state of FIG. In addition, the fitting projections 118a and 118b of the cassette holder 114 move to the lower end side of the inclined holes 120a and 120b of the slide piece 119 as the pivot plate 111 rotates in the clockwise direction. Guided to the inclined holes 120a and 120b, the cassette holder 114 is lowered while maintaining a horizontal state (parallel to the main board 3), and as shown in FIG. 15, the tape cassette 115 is loaded to an operating position. do. In connection with the loading operation of the tape cassette 115, a motor switch (not shown) is turned "on" and the tape drive motor 5 rotates. As the motor 5 rotates, both capstan shafts 7a and 7b are rotated in the direction of the arrow through the belt-type rotational transmission mechanism.

Next, the play operation will be described.

After the loading operation of the tape cassette 115 is completed, when the operation switch (not shown) is turned "on", only the electromagnet 46 for play is "on", and one end of the first amateur 49 is attached to the suction portion 46a. The to-be-adsorbed portion 49a is rotated in the counterclockwise direction while the rotating lever 53 rotates in the counterclockwise direction with the proximal end portion 53a as the point. The engagement lever 56a of the pull arm 56 is engaged with the engagement recess 54 by this rotation lever 53 rotating. On the other hand, since the engagement piece 67 abuts on one side end of the slide lever 55, the second armature 50 is prevented from rotating in the clockwise direction, and thus the second armature 50 is played. It is not adsorbed by the electromagnet 46.

On the other hand, since the second cam gear 61 is already engaged with the small-diameter gear 36 in the stationary state (state of FIG. 1), the rotational force of the tape drive motor 5 is the gear-wheel rotational transmission mechanism ( The second cam gear 61 is cut through the first gear 9, the second gear 10, the third gear 11, the fourth gear 12 and the small-diameter gear 36 of FIG. The second cam gear 61 rotates in the direction of the arrow. In accordance with the rotation of the second cam gear 61, the swing lever 58, which is slid to the cam 62 via the cam roller 60, is clockwise in the state of FIG. 2 with respect to the installation shaft 59. As shown in FIG. Rotate in the direction.

By the rotation of the swing lever 58, the engaging piece 56a of the pull arm 56 on the same axis as the other pinch roller arm 37b is engaged with the engaging recess 54 of the pivot lever 53. Therefore, as the pull arm 56 rotates in the counterclockwise direction, the slide lever 55 moves in the direction of arrow C integrally with the rotation lever 53, and the state is shown by the solid line of FIG. 3 in the state of FIG.

As the slide lever 55 moves in the direction of arrow C, the engaging piece 67 of the pull arm 56 is engaged with the engaging hole 70, so that the second armature 50 is a spring 69. Rotates in the clockwise direction with the elastic bearing force, and the adsorbed portion 50a is adsorbed to the adsorption portion 46b at the other end of the electromagnet 46 for play.

As a result, the slide lever 55 is maintained in the state of moving in the arrow C direction. The head extrusion spring 63 rotates counterclockwise in accordance with the degree of movement of the slide lever 55 in the direction of the arrow C. The press body 65 also rotates counterclockwise according to the rotation, and the press body 65 A part of presses the first blood pressing portion 64 of the head mounting plate 19. By this pressing, the head mounting plate 19 moves in the direction of arrow A against the elastic bearing force of the head return spring 25. At this time, the high speed rotation switching lever 88 is in a neutral position (the state in which the teeth do not mesh with any of the high speed reel gears 18a and 18b, i.e., the state in FIG. 7). Therefore, the head mounting plate (1) until the stopper protrusion 91 protruding from the high speed rotation switching lever 88 abuts against the first contact portion 92a of the engaging hole 92 of the head mounting plate 19. 19 is moved by the stroke S in the direction of the arrow A to the play position, and the magnetic head 23 contacts the tape 115b of the tape cassette 115. When the moving plate 30 is in the position moved in the direction of arrow C when the head mounting plate 19 is moved to the play position (state of FIG. 1), the moving plate is moved in accordance with the movement of the head mounting plate 19 to the play position. The support member 27 is guided by the guide edges 31b and 31a of the guide hole 31 of the 30 to move in the direction of arrow C together with the low speed rotation switching gear 28, thereby providing a low speed rotation switching gear ( The gear 28 meshes with the sixth gear 14 of the gear type rotary transmission mechanism 8 and the low speed rotation reel gear 17b on the other side of the reel support 6b. As a result, the rotational force of the tape drive motor 5 is reduced by the first gear 9, the second gear 10, the third gear 11, and the fourth gear 12 of the gear-wheel rotational transmission mechanism 8. And, via the fifth gear 13, the sixth gear 14, the low speed rotation switching gear 28 and the other low speed rotation reel gear 17b, are transferred to the other reel support 6b. The side reel support 6b is rotated at a low speed (normal speed) in the counterclockwise direction. Moreover, when the rod spring 41 is in the position which moved the arrow C direction with the moving plate 30 (state of FIG. 4), the contacting bent part 41a of the single-stage shaft of the rod spring 41 will become one side. Since the abutting bent portion 41b on the other end side abuts against the guide piece 45a, is out of the other guide piece 45b, the other pinch roller arm 37b is used as the elastic support force of the bar spring 41. The pinch roller 38a does not contact one capstan shaft 7a while being rotated clockwise and in contact with the other capstan shaft 7b through the tape 115b and rotating clockwise. For this reason, while the tape 115b is wound from one reel support 6a side to the other reel support 6b side, play operation | movement is performed.

Moreover, when the moving plate 30 is in the position moved to the arrow D direction at the time of the movement of the head mounting plate 19 to the play position, the moving plate 30 will move in accordance with the movement to the play position of the head mounting plate 19. The low speed rotation switching gear 28 is sawed because the support member 27 moves in the direction of the arrow D together with the low speed rotation switching gear 28. The eighth gear 16 of the wheel-type rotation transmission mechanism 8 meshes with the gear for low speed rotation reel gear 17a on one side of the reel support 6a. As a result, the rotational force of the tape drive motor 5 is controlled by the first gear 9, the second gear 10, the third gear 11, the fourth gear 12, The other reel bearing 6a is provided through the fifth gear 13, the seventh gear 15, the eighth gear 16, the low speed rotation switching gear 28 and the other low speed rotation reel gear 17a. ), The other reel support 6a is rotated at a low speed (normal speed) in the counterclockwise direction. Moreover, the bar spring 41 is in the position which moved the arrow D direction with the moving plate 30, and the contacting bent part 41b of the other end side of the bar spring 41 is attached to one guide piece 45b. The abutting bent portion 41a on the one end side is abutted from the other guide piece 45a, so that the other pinch roller arm 37a moves counterclockwise as the elastic bearing force of the rod spring 41. It rotates and contacts the other capstan shaft 7a through the tape 115b, rotates counterclockwise, and the other pinch roller 38b does not contact the other capstan shaft 7b. For this reason, while the tape 115b is wound around the other reel base 6a side, a play operation | movement is performed.

Next, the autoreverse operation will be described.

For example, as shown in FIGS. 3 and 4, in the state in which the play motion is performed while winding the tape 115b from one reel support 6a side to the other reel support 6a side, Since the friction plate 107b is rotated counterclockwise, the pin 108a rotates counterclockwise by pressing the contact piece 105c on the other side of the rocking arm 105. Thus, since the swing arm 105 is provided with a rotational force in the counterclockwise direction, as long as the friction plate 107b is rotated, the cam sliding joint 105d of the swing arm 105 has a gear-wheel rotational transmission mechanism 8. ), The small-diameter gear 36 and the teeth are always in contact with the first cam 109 of the first cam gear 35 which rotates in the clockwise direction.

Then, when all the tapes 115b are wound around the reel support 6b on the one side of the reel support 6a and reach the tape end, the friction plate 107b also stops with the reel support 6b. As a result, the rotational force in the counterclockwise direction with respect to the rocking arm 105 cannot be imparted. Due to this, the rocking arm 105 is rotated clockwise by the action of the first cam 109 of the rotating first cam gear 35 and is farthest from the center of the first cam 109. The rocking arm 105 stops in a state where the protrusion 105d is in the sliding engagement position. Then, since the second cam 110 of the rotating first cam 109 enters the state between the first cam 109 and the cam sliding protrusion 105d, the rocking arm 105 is clockwise again. It is greatly rotated by. The protrusion 105a is rotated counterclockwise by the rotation of the rocking arm 105 so that the contact portion 94a is cam 93 of the binder gear 33. It comes out of the contact end part 93a to one side of the. As a result, the rotation restrictions on the gear 33 are released. Here, the switching operation body 150a of the moving plate 30 and the head channel switching switch 150 is connected through the spring 149, and the moving plate 30 is pressed in the direction of arrow C, and this spring 149 Since the switching operation body 150a is going to return to the arrow D direction by the reaction force of the reaction force, the engagement hole 32 of the moving plate 30 and the engagement pin 34 of the engagement gear 33 are engaged with each other. As a result, the rotational force in the clockwise direction is applied to the gear 33. However, since the abutted part a of the first trigger arm 94 is engaged with the abutting end 93a or 93b of the cam 93 of the toothing gear 33, the toothed gear The clockwise rotation of 33 is inhibited.

As described above, the engagement gear 94a of the first trigger arm 94 deviates from one of the abutting end portions 93a of the first engagement gear 93a. Rotate clockwise until the teeth engage with (35). After the gear is engaged with the first cam gear 35, the binder gear 33 rotates approximately 180 degrees clockwise by the rotational force of the first cam gear 35. The moving plate 30 connected through the engaging piece 34 and the engaging hole 32 moves in the direction of arrow D in the position of FIG. The head channel selector switch 150 is changed in accordance with the movement of the moving plate 30 in the direction of arrow D, and is guided by the guide edge 31a of the guide hole 31 of the moving plate 30 to support member 27. ), The low-speed rotational switching gear 28 moves in the direction of the arrow D, and the cogwheel rotary transmission mechanism 8 moves the low-speed rotational reel gear on the side of the eighth gear 16 and one reel support 6a. A tooth is engaged with 17a, and this one reel base 6a is rotated counterclockwise at low speed.

In addition, as the rod spring 41 also moves in the direction of the arrow D integrally with the moving plate 30, one pinch roller arm 37a is rotated counterclockwise as an elastic bearing force of the rod spring 41, and one pinch is rotated. The roller 38a contacts one capstan shaft 7a through the tape 115b, and the other pinch roller arm 37b is rotated counterclockwise so that the other pinch roller arm 38b is on the other side. It separates from the capstan shaft 7b. As a result, the tape running direction is set halfway, and the tape 115 is wound from the other reel support 6b side to the one side of the reel support 6a, whereby the play operation is performed. Rotation force is imparted to the rocking arm 105 in a counterclockwise direction while the pin 108a of the friction plate 107a rotating according to this play presses the contact surface 105b of the rocking arm 105. Then, the cam sliding joint 105d comes into contact with the first cam 109 of the first cam gear 35 and the first trigger arm 94 returns due to the elastic bearing force of the return spring 104. The contact gear 94a rotates in a direction so that the contact gear 33 restrains rotation again by contacting the other contact end portion 93d of the cam 3 of the engagement gear 33.

Thereafter, each time the tape end is reached, the above operation is repeated to perform the autoreverse operation.

Next, the manual reverse operation will be described.

For example, as shown in FIG. 4, a manual tape traveling direction switching switch (not shown) is shown when the play operation is performed while winding the tape 115b from one reel support 6a side to the other reel support 6b side. Is "on", the ejection electromagnet 101 is "on". In this case, together with the plunger 101a, the movable plate 100 moves in the direction of arrow B against the elastic bearing force of the return spring 102. In accordance with this movement, the second trigger arm 96 rotates in the counterclockwise direction. Then, the pin 97 rotates the first trigger arm 94 in the counterclockwise direction so that the abutted portion 94a is disengaged from the abutting end 93a of one of the engagement gears 33. Due to this, the gear 33 rotates in the clockwise direction so that the first cam gear 35 and the teeth mesh with each other, and the first cam gear 35 causes the tooth gear 33 to clockwise. The rotation plate 30 moves in the direction of arrow D according to the rotation by approximately 180 degrees, and the movement plate 30 moves in the direction of arrow D according to this rotation, and one reel support 6a is similar to the above-described autoreverse operation. ) Is rotated clockwise by the rotational force of the tape drive motor 5, while one pinch roller 38a contacts the one capstan shaft 7a and the other pinch roller 38b is the capstan shaft 7b. The tape 115b is wound from the other reel tip 6b side to the one side of the reel base 6a, and a play operation, that is, a reverse operation by a manual, is performed.

Next, the fast forward operation will be described.

For example, as shown in FIG. 4, when the play operation is performed while winding the tape 115b from one reel support (a) side to the other reel support 6b side, a fast-sending operation switch (not shown) is " When it is turned "on", the electromagnet 46 for play which has been "on" until then turns "off", and the electromagnet 46 for fast delivery and the electromagnet 48 for quick delivery are "on" at the same time. That is, the slide lever 55 is moved in the direction of the arrow D in the state of the solid line of FIG. 3 by the elastic bearing force of the head extrusion spring 63 by "off" of the electromagnet 46 for play, which was "on" until then. In this figure, the process returns to the position indicated by the dashed-dotted line. By this twisting force, the pull arm 56 rotates clockwise and the swing lever 58 counterclockwise, respectively. As a result, the cam roller 60 of the swing lever 58 slides to the nearest portion from the farthest portion from the center of the cam 62 of the second cam gear 61 and thus the second cam gear ( 61 rotates counterclockwise so that the second cam gear 61 meshes with the small-diameter gear 36 of the cogwheel rotational transmission mechanism 8. After that, the second cam gear 61 is rotated approximately one revolution in the counterclockwise direction by the rotational force of the predetermined gear 36.

Then, as the electromagnet 46 for play is turned "on", the slide lever 55 moves in the arrow C direction as in the above-described play operation.

On the other hand, the adsorbed portion 72a of the fourth armature 72 is adsorbed by the adsorption portion 48a of the fast-moving electromagnet 48 while the quick-delivering electromagnet 48 is turned "on". The amateur 72 is rotated clockwise.

In response to the rotation of the fourth amateur 72, the tape travel direction switching member 75 is pressed by the pressing end 72b while pressing the other projection 75b of the tape travel direction switching member 75. Rotate counterclockwise in FIG. According to this rotation, the rotation member 79 moves in the arrow A direction in FIG. In this state, as the slide lever 55 moves in the direction of arrow C in the state of FIG. 7, the push lever 83b at the other end of the slide lever 55 is pushed 81b at the other side of the pivot member 79. Press).

Therefore, the rotation member 79 rotates clockwise about the support shaft 80. In accordance with the rotation of the pivot member 79, the slide plate 85 moves in the direction of arrow D, and the high-speed rotation switching lever 88 connected thereto via the connecting spring 87 is clockwise at the neutral position in FIG. Rotate in the direction.

On the other hand, as the slide lever 55 moves in the direction of arrow C, the head mounting plate 19 moves in the direction of arrow A similarly to the above-described fryer operation. In this case, since the high speed rotation switching lever 88 is rotated in the clockwise direction as described above, the third of the engaging hole 92 of the head mounting plate 19 is connected to the stopper projection 91 of the high speed rotation switching lever 88. As the abutting portion 92c abuts, the movement limit position in the direction of arrow A of the head mounting plate 19 is defined, and the stroke becomes S _{1, which} becomes smaller than the stroke S in the play operation. As a result, the gear for the low speed rotation switching gear 28 is not engaged with any gear and the magnetic head 23 is not in contact with the tape cassette 115b, so that the other pinch roller 38b is the capstan shaft. (7b "), and the high speed rotation switching gear 90 has the high speed rotation of the 5th gear 13 and the other side of the reel support 6b of the gear type rotary transmission mechanism 8. As shown in FIG. The teeth engage with the dedicated reel gear 18b (state of Fig. 9.) As a result, the other reel support 6b is rotated at a high speed in the counterclockwise direction and the other reel is supported on the one side of the reel support 6a. The tape 9215b is quickly sent to the support 6b side.

Next, the rewind operation will be described.

For example, as shown in FIG. 4, when the play operation is performed while winding the tape 115b from one reel support 6a side to the other reel support 6b side, a rewind operation switch not shown is shown. When it is turned "on", the Frey electromagnet 46, which has been "on" until then, becomes "off", and the electromagnet 46 for winding and the electromagnet 47 for winding are turned "on" at the same time. That is, the slide lever 55 is indicated by the dashed-dotted line in the state of the solid line in FIG. 7 in the same manner as in the case of the fast forwarding operation described above by the " off " By returning to the position, the return arm rotates the pull arm 56 clockwise and the swing lever 58 counterclockwise, respectively. As a result, the cam roller 60 of the swing lever 58 slides to the nearest portion from the position farthest from the center of the cam 62 of the second cam gear 61 and thus the second cam gear ( 61 rotates counterclockwise so that the second cam gear 61 meshes with the small-diameter gear 36 of the cogwheel rotational transmission mechanism 8.

Subsequently, the second cam gear 61 is rotated approximately one revolution in the counterclockwise direction by the rotational force of the small-diameter gear 36. Then, the slide lever 55 is moved in the direction of the arrow C as in the above-described play operation, by turning the prey electromagnet 46 back on.

On the other hand, by the "on" of the winding electromagnet 47, the adsorption portion 71a of the third armature 71 is returned and adsorbed to the adsorption portion 47a of the electromagnet 47 for winding. The amateur 71 is rotated counterclockwise. In response to the rotation of the third amateur 71, the tape travel direction switching member 75 is pressed by the pressing end 71b while the tape travel direction switching member 75 presses one projection 75a. Rotate clockwise at 7 degrees.

According to this rotation, the rotation member 79 moves in the arrow B direction in FIG. In this state, as the slide lever 55 moves in the direction of arrow C in the state of FIG. 7, the pressing portion 83a on the first end side of the slide lever 55 is the pressed portion 81a on the one side of the pivot member 79. Press. Therefore, the rotation member 79 rotates counterclockwise about the support shaft 80. In accordance with the rotation of the pivot member 79, the slide plate 85 moves in the direction of arrow D, and the high speed rotation switching lever 88 connected thereto via the coupling spring 87 is counterclockwise at the neutral position in FIG. Rotate in the direction.

On the other hand, as the slide lever 55 moves in the direction of the arrow C, the head mounting plate 19 moves in the direction of the arrow A similarly to the above-described play operation. In this case, since the above-mentioned high speed rotation switching lever 88 is rotated counterclockwise, the stopper projection 91 of the high speed rotation switching lever 88 is made of the engaging hole 92 of the head mounting plate 19. As the two abutting portions 92b abut, the movement limit position in the direction of the arrow A of the head mounting plate 19 is regulated, and this stroke becomes S ₁ . Thus, the low speed rotation switching gear 28 is not in engagement with any of the gears, and the magnetic head 23 does not come into contact with the tape 115b of the tape cassette 115. Does not contact the capstan shaft 7b. The high speed rotation switching gear 90 meshes with the seventh gear 15 of the gear type rotary transmission mechanism 8 and the high speed rotation reel gear 17a on one side of the reel support 6a. (State of FIG. 10). As a result, one reel support 6a is rotated at high speed clockwise, and the tape 115b is wound back at a high speed from the other reel support 6b side to the one of the reel support 6a sides.

Next, the eject operation will be described.

For example, when the eject operation switch (not shown) is turned "on" during the play operation, only the eject electromagnet 101 is "on" after the play electromagnet 46 which has been "on" until then is "off". . In this case, the movable plate 100 moves in the direction indicated by the arrow B against the elastic bearing force of the return spring 102 and thus rotates clockwise at the position indicated by the two-dot chain line in FIG. 18. In this figure, a solid line is shown. Then, the hook portion 140 of the eject plate 138 is engaged with the engaging end 141 of the swing lever 58. As a result, the swing lever 58 is rotated in the clockwise direction as the action of the cam 62 which rotates by engaging the small-diameter gear 36 and the teeth. According to this rotation, it moves in the direction of arrow C against the elastic bearing force of the eject lever 124, the slide piece 119, the return spring 125, and 121 with the eject plate 138. As shown in FIG. According to this movement, the contacting edge 124a at the tip of the eject lever 124 contacts the contacting piece 111c of the rotating plate 111 as indicated by the double-dotted line in FIG. 15 to rotate the rotating plate ( 111) rotates counterclockwise. In accordance with this rotation, the cassette holder 114 is raised while maintaining a parallel state with the main board 3.

Then, the rotating plate 111 and the cassette holder 114 are engaged by engaging the hook 135 of the slide piece 119 and the engaging claw 136 of the hook plate 133 abut on the upper edge of the slide piece 119. ), The eject lever 124 and the slide piece 119 are maintained in the state of FIG. 14 and FIG.

On the other hand, as the spring support plate 130 rotates counterclockwise in FIG. 13 through the rod 129 as the eject lever 124 moves in the direction of arrow C, the elastic bearing force of the reverse spring 131 is reversed. The elastic support force causes the slider 132 to move in the direction of the arrow D, whereby the tape cassette 115 is ejected outward (arrow D direction) as shown in FIG. 12 from the insertion slot 114a of the cassette holder 114. do. In connection with the ejection operation of the tape cassette 115, the motor switch is " off ", and the rotational force of the tape drive motor 5 is stopped.

Then, when the ejector electromagnet 101 has failed, the first roller 114 of the slide piece 119 is moved by moving the eject lever 124 in the direction of arrow C against the elastic bearing force of the return spring 125 by manual operation. ) Presses the rotating body 142. Thereby, the rotating body 142 rotates clockwise, and the pressing part 142b presses the 2nd to-be-pressed part 145 of the head mounting plate 19. As shown in FIG. As a result, the head mounting plate 19 moves in the direction of arrow B against the elastic bearing force of the head extrusion spring 63. As a result, the eject operation can be performed as a manual operation. In addition, when the play electromagnet 46 tries to play in the " off " state, the cam sliding engagement portion 105d of the rocking arm 105 is the cam of the cam 109 of the first cam gear 35. If the position is far from the surface, the autoreverse operation is performed immediately after the start of the play operation. Therefore, in the state just before the start of the play operation, it is necessary to set the cam sliding joint 105d of the rocking arm 105 to a position approaching the cam surface of the cam 109. Thus, when the electromagnet 46 for play is " off ", as shown in FIG. 6, the detector 104 is elastically supported in the direction of arrow A by the spring 104 as the second engaging stone piece 100c. While pressing the projection 105a of the rocking arm 105, the cam sliding joint 105d is brought into contact with the cam surface of the cam 109. Then, while the electromagnet 46 for play is "on" and the second armature 50 rotates clockwise, the detector lever 103 moves in the direction of arrow B against the elastic bearing force of the return spring 104, As shown in FIG. 6, the second engaging stone piece 103c is separated from the projection 105a of the rocking arm 105 so that the detector lever 103 does not engage with the rocking rock 105 at all. . In addition, the engaging projections 148a and 148b of the gear 33 are provided, and if the abutted portion 94a of the first trigger arm 94 contacts the abutment portion 93a or 93b of the cam 93. ), The contacting portion 94a abuts against the engaging projection 148a or 148b so that the rotation of the binder gear 33 is regulated to be rotated approximately every 180 degrees. The autoreverse operation is continuously performed by the continuous rotation.

Moreover, since the roller 43 was provided in the center of the rod spring 41, the movement of the rod spring 41 is performed smoothly even with a small force. In addition, since the pressing pieces 147a and 147b are inclined to the upper surface of the main board 3 and a part of the head mounting plate 19 is brought into contact therewith, the head mounting plate 19 is pressed against the main board 3 side. I can do it.

As described above, in the present embodiment, the swinging motion of the swinging lever 58 which is interlocked with the cam 62 of the cam gear 61 driven by the tape driving motor 5 is operated by the play electromagnet 46. It conveys to the slide lever 55.

Then, the rotational movement member 79 supported by the tape traveling direction detection member 75 which rotates the movement of the slide lever 55 in the other direction in the operation of the fast-moving electromagnet 48 or the rewinding electromagnet 47. As the rotary motion member 79 rotates in the other direction, the slide plate 85 connected to the rotary motion member 79 moves to one side or the other from the neutral position.

Then, the high speed rotation switching gear 90 supported by the high speed rotation switching lever 88 is rotated by the high speed rotation switching lever 88 connected to the slide plate 89 via the connection spring 87. Mesh with the high speed reel gear 18a or 18b.

On the other hand, the actuation of the electromagnet for play operates the head moving mechanism and moves the head mounting plate in the direction of arrow A, or the head mounting plate moves in the direction of arrow A because the high speed rotation switching lever 88 is rotating in the neutral position. It is regulated and the pinch roller and capstan are separated.

Therefore, by operating the electromagnet corresponding to each operation mode, it is possible to switch the desired operation from a single drive source.

The effect of this design is as follows.

As described above, the tape recorder device according to the present invention has a cam portion and is rotated by a tape driving motor, and the swing lever and the electromagnet for play, and the electromagnet for play, which are rotated in conjunction with the cam gear. Tape traveling moving in opposite directions by the head moving mechanism driven by the swing lever, each of the electromagnets for fast forwarding and rewinding, and the electromagnets for fast forwarding or rewinding, usually in a neutral position. A direction detecting member, a rotating member which is rotatably supported by the detecting member and is displaced according to the position of the detecting member and driven by the head moving mechanism to rotate in a different direction to the displacement position, and interlocked with the rotating member Equipped with a high speed transmission mechanism for high speed transmission of the rotational force of the motor on one or the other of the reel support It is characterized by one.

Therefore, the high speed rotation transmission mechanism for selecting which head moving mechanism and which of the left and right reel supports to rotate at high speed can be operated by using the rotational force of the tape drive motor by a simple structure.

Claims (1)

Cam gear 61 which is rotationally driven by the tape driving motor 5, and swing lever 58 which engages with the cam part 62 of this cam gear 61 and oscillates by rotation of this cam gear 61. And head moving mechanisms 19, 53, 55, 63, 65 which are selectively engaged with the swing lever 58 and driven by the swing of the swing lever 58, and the head moving mechanisms 19, 53, 55. Selectively rotates the rotational force of the motor 5 on the electromagnet 46 for play and the one or the other receptacles 6a and 6b for selectively controlling the engagement with the swing lever 58 of FIGS. It is driven by the high speed rotation transmission mechanism (85, 87, 88, 90) and the head moving mechanism (19, 53, 55, 63, 65) to transmit and rotate the motor (5) according to the direction of the rotational movement Rotation member 79 for selectively operating the high speed rotation transmission mechanism (85, 87, 88, 90) by selectively determining the reel (6a, 6b) for transmitting the rotational force of the rotational speed, and for the feed and rewind And a tape traveling direction detecting member 75 which displaces in the opposite directions by selective energization of the magnets 48 and 49 to regulate the direction of the rotary motion of the rotary motion member 79, and a tape, characterized in that Recorder device.