KR900001145B1 - Cassette deck - Google Patents

Abstract

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Description

Cassette deck

1 is a perspective view showing a cassette deck and the whole according to the present invention.

2 is an exploded perspective view of the internal structure of the cassette deck.

3 to 8 are partial detailed perspective views of this internal structure.

9 and 10 are plan and back views, respectively, of this internal structure.

11 to 18 show this internal structure in detail.

19 to 26 are diagrams illustrating the operation of the cassette deck.

* Explanation of symbols for main parts of the drawings

1: cassette deck 20, 35: gear transmission mechanism

33: first gear 34: second gear

39: control panel 49: magnetic head

73: star art trigger lever 75: magnetic head switch command rod

The present invention relates to a cassette deck. Cassette decks have tended to be smaller in recent years, and particularly in cassette decks mounted on a vehicle, there is a strong demand for miniaturization because the space for accommodating the cassette deck is limited.

In addition, in the case of playing a 4-track magnetic tape recorded in both normal and reverse directions, the cassette half is inverted and replaced when one-way playback is finished, but the cassette eliminates this change and hassle. As a deck, a so-called auto reverse mechanism has been developed. As is well known, the Auto Reverse mechanism automatically reverses the magnetic tape and sets the magnetic head to match the track in both directions.

Several configurations have already been proposed for switching magnetic heads to forward and reverse, but for example, when reproducing four-track magnetic tapes, four magnetic heads are provided so that two channels of each of these four channels are electrically matched with the reversed driving of magnetic tapes. A switchable type or a two-channel magnetic head is provided so that the main body of the magnetic head can be mechanically moved or rotated in parallel with the forward and reverse running of the tape. Among these various types of magnetic head switching, the Adimas adjustment can be performed independently for both the magnetic tape and the forward / reverse bidirectional driving. Therefore, a better reproducing frequency characteristic can be obtained than other types, so that the magnetic head is rotated. It is becoming.

In the magnetic head rotation type, the magnetic head is once moved in a direction substantially perpendicular to the tape running direction to disengage the magnetic head from the magnetic tape and then rotated, and then the magnetic head is moved again to contact the magnetic tape.

In the cassette deck already developed, a drive source for rotating the magnetic head and a drive source for reciprocating the magnetic head in a direction substantially perpendicular to the tape traveling direction are provided separately from the drive source, that is, at least two drive sources. Therefore, there has been a problem in miniaturization and cost reduction of the entire cassette deck.

SUMMARY OF THE INVENTION The present invention has been made in view of the foregoing, and an object thereof is to provide a cassette deck which is easy to be miniaturized as a whole cassette deck and is inexpensive.

The cassette deck according to the present invention includes a head restraint freely reciprocated in a direction substantially perpendicular to the tape traveling direction, and between two angular positions with respect to an axis approximately parallel to the head direction in the movement direction of the head restraint. And a head to drive mechanism including a magnetic head freely rotatable, a tape running direction switching means for defining a tape running direction corresponding to the angular position of the magnetic head, and a first gear for reciprocating the head stand by rotation. And a gear transfer mechanism capable of engaging with the second gear for rotating the magnetic head, wherein the first and second gears include a rotation force imparting mechanism for imparting rotational force from a single drive source, wherein the first gear includes: The striker means for engaging the second gear with the gear transmission after being engaged with the gear transmission. And the trigger means is reciprocated freely installed between the highest and lowest travel positions and is swung by the rotation of the first gear, and is engaged with the second gear when it is not in the maximum return position. The control panel is provided with a control unit for regulating the rotation of the gear, a biasing means for applying the force in the double-direction direction to the control panel, and when the control panel reaches the highest moving position, prohibiting the actuation of the control panel and starting the first gear. Prohibition means for releasing this prohibition by means, and a biasing means for applying a force in a direction in which the first and second gears engage with the gear transmission mechanism, and the head stage rotates 360 ° by rotating the first gear. One operation of double acting is performed, and the second head rotates by 180 °. The magnetic head rotates by 180 °.

EXAMPLE

Hereinafter, a cassette deck as an embodiment of the present invention will be described with reference to the accompanying drawings.

In the drawings, reference numeral 1 denotes the entire cassette deck.

As shown in FIG. 1, the front part of the housing 2 is provided with the elongate rectangular opening 2a for inserting a cassette half (described later). In this case, the term "forward" refers to a direction indicated by an arrow (Y) in the figure, and the term "left-right" is directed forward. Therefore, the arrow X direction is toward the left and the arrow Z direction is upward.

As shown in FIGS. 2, 3, 9, and 10, a chassis 3 made of steel sheet or the like is provided in the housing 2. As shown in FIG. 4, on the chassis 3, a pair of rail units 5 are arranged side by side in the front-rear direction, and rotation is freely attached to the chassis. As is apparent from FIG. 11, the reel unit 5 has a rotational center shaft 5a fixed to the chassis 3. The rail 5b is freely fitted to the rotation center shaft 5a from outside. The collar 5c and the bush 5d are fitted to the upper end and the lower end of the rail 5b, respectively. The collar 5c is embedded in the cassette half and can be interpolated in the cassette rail wound around the magnetic tape. The enlarged diameter part 5e which enlarged the diameter in the disk shape is formed in the center part of the rail 5b, The double gear 5f in which two gear parts were formed large and small is arrange | positioned between this expanded diameter part and the bush 5d, In addition, rotation is freely attached to the rotation center shaft 5a. A coil spring 5g is applied between the double gear 5f and the bush 5d to apply a force in a direction in which the double gear and the bush are separated from each other. The rail 5b is provided with a felt plate 5h between the enlarged diameter portion 5e and the double gear 5f. The felt plate 5h is attached to the enlarged diameter portion 5e and abuts against the double gear 5f so as to be movable.

An arm 5i is provided between the upper surface of the enlarged diameter portion 5e and the collar 5c, and the rotation is freely attached to the rail 5b and the outside at one end thereof.

The lower surface and the upper surface of the arm 5i are engaged so as to slide freely by inserting the enlarged diameter portion 5e, the collar 5c, the washers 5j, 5k of the rail 5b, and the upper washer 5k. And a coil spring 5l that exerts a force downward on the arm is disposed between the arm 5i.

As shown in FIG. 2, FIG. 3, FIG. 9, and FIG. 10, in the right direction of the rail unit 5, the intermediate lever 7 is arranged to extend substantially in the front-rear direction, and the pin 7a ), Rotation is freely attached to the chassis 3 in a plane parallel to the main surface of the chassis.

A rectangular opening 7b is formed at the front end of the intermediate lever 7, and a fin 8a protruding from the center of the flow lever 8 in which flow freely flows over the chassis 3 is formed in the opening. The flow is freely fitted.

The floating lever 8 is provided with pins 8b protruding from both ends thereof, and the respective pins are freely slid into the long holes 5m formed at the free ends of the reel unit 5 and the arm 5i. Lost

As shown in FIG. 7 and FIG. 18, the end detection lever 10 is arrange | positioned in the vicinity of the rear end part of the intermediate lever 7. As shown in FIG.

The end detection lever 10 is one end of the rotation of the lever A (12), which is freely rotatable in the sub chassis A (11), which protrudes upward on the rear surface of the rear end of the chassis (3). On the right end of A, a drive is freely attached to the upper end.

The lower end of the end detection lever 10 is provided with a projection 10a extending downward, which is freely slid to the cutout portion 7c formed at the rear end of the intermediate lever 7 so as to be movable. have.

As shown in Figs. 7, 9 and 18, the pin 106 protrudes from the rear of the lower end of the end detection lever 10, which is freely rotatably attached to the subchassis A and the end detection. It is engaged with the end detection gear 14 which opposes the rear end surface of the lever 10. As shown in FIG. As is clear from Figs. 7 and 18, a concave portion 14a is formed on an opposing surface of the end detection gear 14 and the end detection lever 10, and in the radial direction of the end detection lever around the concave portion. Three mountainous protrusions 14b each having the same shape, which protrude, are provided with a pitch of 120 degrees. In the center of the recess 14a, three projections 14c each having the same shape extending radially toward the valleys between the above-described mountainous protrusions 14b are formed. In the case where a circle circumscribed at the top of each of the protrusions 14b and a circle resistant to the top of the corner protrusion 14c are simulated, the diameters of these circles are approximately the same dimension. The pin 10b protruding from the end detection lever 10 can engage with these protrusions 14b and the protrusion 14c.

Of the tape end detection mechanism for detecting the magnetic tape and the end played by the rail unit 5, the intermediate lever 7, the floating lever 8, the end detection lever 10, and the end detection gear 14 described above. Some are composed.

4n gears 16, 17 and 18 meshed in series with the left side of the end detection gear 14 as the rear face of the subsash 11, as shown in FIGS. 2, 7, 9 and 18 The gear transmission mechanism 20 which consists of 19 is provided, and the end detection gear 14 is meshed with the last gear 19 of this gear transmission mechanism. As shown in FIG. 18, the ultra-short gear 16 of the gear transmission mechanism 20 (wherein reference numeral 20 is not shown in FIG. 18) is freely rotatably attached to the subchassis 11. It meshes with the worm 22. The pulley 23 is integrally formed at the worm 22 and the lower end. As shown in FIG. 10, the pulley 23 is rotationally driven through the belt 25 by a motor 24 disposed at the right rear end of the chassis 3. In addition, the belt 25 is directly enclosed by the small pulley 24a fitted to the output shaft of the motor 24.

As is apparent from FIG. 10, the belt 25 also spans a pair of flywheels 27 provided with rotations freely paralleled to the bottom surface of the chassis 3 in front and rear. However, the direction of rotation of the motor 24 is the forward direction of the arrow (N), while the pulley (23) in the direction of the arrow (N), and a pair of flywheels 27, respectively, the arrow (0) And the belt 25 so as to always rotate in the direction P).

The flywheel 27 has gear parts 27a and 27b of large and small in the outer peripheral part and the inner peripheral part. The smaller gear portion 27b of the two gear portions formed in the flywheel 27 is engaged with the large-size gear portion of the double gear 5f of the reel unit 5 through a pair of idler gears 28 before and after. It is. As is apparent from FIG. 2, FIG. 3, and FIG. 9, these gear gears 28 rotate at one end of the swinging lever of the support lever 30 in which the swing is freely installed through the shaft member 30a in the chassis 3. The freely attached one is detached from the double gear 5f of the rail unit 5 by swinging the support lever. In addition, the support lever 30 has a force applied in a direction in which the idler gear 28 approaches the double gear 5f by the coil spring 30b.

As shown in FIGS. 2, 7, 9 and 18, the rear surface of the subsash 11 has a first gear 22 and a second gear 34 above the gears 16 to 19. The rotation is freely attached. The first gear 33 is engaged with the gear 16 of the gear transmission mechanism 20 (for example, see FIG. 7), and the second gear 34 is engaged with the gear 18 of the gear transmission mechanism.

Here, the gear transmission mechanism 20, the worm 22, the pulley 23, the bend 25, etc. are used as the single drive source to the first gear 23 and the second gear 34 from the motor 24. A rotation force applying mechanism for imparting rotational force is configured. Moreover, this rotation force provision mechanism and the rotation force provision means which rotationally drive the 1st gear 33 and the 2nd gear 34 by the motor 24 are comprised.

The 1st gear 33 is for reciprocating the head stand mentioned later, First, the structure which connects this 1st gear and this head stand is demonstrated.

For example, as shown in Figs. 7 and 18, a pin 33a protrudes from the rear surface of the first gear 33, and the first gear 33 is clockwise in Fig. 18 on this pin. One end of the coil spring 35 to apply a force to it. The coil spring 35 is hung on the other end of the plate 36 fixed to the distal end of the gear 16 and the center of rotation (not shown) of the gear 18.

As shown in Figs. 2, 3, 9 and 11, at the rear end of the chassis 3, i.e., behind the sub chassis A 11, in parallel with the sub chassis A 11; The curved part 3a extended upward is formed. As shown in FIG. 4, the control panel 39 which consists of steel plates is attached to the front surface of this curved part 3a freely to move from left to right. The movement limit position on the left side of the control panel 39 is referred to as the lowest moving position of this control panel, and the movement limit position on the right side is called the least double-acting position. The right end of the control panel 39 is connected to a coil spring 40 which applies the force to the right side, that is, in the double-direction direction. A protrusion 39a to which the pin 33a of the first gear 33 can engage is formed at an upper end of the substantially central portion of the control panel 39. The protrusion 39a is engaged with the pin 33a at the right edge thereof, so that the control panel 39 is swung by the rotation of the first gear 33. As shown in FIG. 2, FIG. 4 and FIG. 10, the lever B 42 which is connected to the lower side of the control panel 39 through the control panel and the coil spring 41 and moves to the left according to the fluctuation of the control panel. ) Is arranged. The right end of the lever B 42 is provided with a projection 42a that engages with the right edge of the projection 39b formed at the lower end of the control panel 39, whereby the force of the coil spring 40 is applied. In accordance with the double acting of the control panel 39, the lever B 42 is also returned to the right side. As is apparent from FIGS. 2, 8 and 10, the left end of the lever B 42 extends forward and backward on the lower surface of the chassis 3, and is freely rotated at its central portion via the pin 44a. It is conically joined to the rear end of the lever C 44 attached to the chassis 3. The front end of the lever C 44 is conically joined to the head rest 47 on which the reciprocating movement is freely performed on the chassis 3 in the left-right direction. In addition, the traveling direction of the magnetic tape is the front-rear direction, and therefore the moving direction of the head rest 47 is substantially perpendicular to this tape traveling direction.

The head stage 47 is driven by the first gear 33, the control panel 39, the coil springs 40 and 41, the lever B 42 and the lever C 44, and peripheral elements associated therewith. The head stand drive mechanism for this is comprised.

Next, the second gear 34 and its related members will be described. The second gear 34 is for rotating the magnetic head 49 provided on the head rest 47, and is disposed farther from the head rest 47 than the first gear 33. Moreover, the rotation ratio of the 1st gear 33 and the 2nd gear 34 is 1: 1.

As is clear from FIG. 7 and FIG. 18, two stop pins 34a and 34b protrude from the rear surface of the second gear 34 at a pitch of 180 degrees, and one stop pin 34a is now provided. The second gear is penetrated to protrude from the front surface of the second gear. In addition, both stop pins 34a and 34b can be engaged with the right edge of the protrusion 39c protruding from the upper end of the rear end of the control panel 39. In other words, the control panel 39 is also driven by the two stop pins. In the vicinity of the second gear 34, a click member 51a and a spring member 51b are provided, and the second gear 34 is clockwise in FIG. 18 by this click member and the spring member. Strength is applied. As shown in FIG. 18, the moving plate 52 made of steel plate is attached to the rear surface of the sub chassis A so as to reciprocate freely in the left-right direction. At the right end of the movable plate 52, click portions 52a and 52b that are engaged with the stop pin 34a protruding from the front surface of the second gear 34 are formed. The click portion 52a is engaged with the stop pin 34a at its right magnetic seat, and the click portion 52b is engaged with the stop pin 34a by its left edge. That is, the movable plate 52 is reciprocated by rotating the second gear 34 in one direction by 180 degrees.

As shown in FIG. 2, FIG. 3 and FIG. 9, the lever D 53 formed in a substantially < shape is disposed in the vicinity of the movable plate 52 and the left end, and the chassis can be freely rotated at its central bend. It is attached to the upper surface of 3). In addition, the lever D 53 is click-pressed by the spring 54 (refer FIG. 3). The left end of the movable plate 52 is conically joined to the rear end of the lever D 53. In addition, the front end of the lever D 53 is conically joined to the rear end of the slide member 56 (shown in FIG. 5) on which the reciprocating movement is freely provided in the front-rear direction on the head rest 47.

As shown in FIGS. 2, 5, and 9, the magnetic head 49 is disposed on the right side of the slide member 56. The magnetic head 49 is a shaft perpendicular to the magnetic tape contact surface of the magnetic head through an axis parallel to the moving direction of the head base 47 by a bearing member 57 fixedly mounted on the head base 47. The rotation is freely supported by the center. The rotating shaft portion of the magnetic head 49 is made of die cast alloy, while the raw material of the bearing member 57 fitted with the rotating shaft portion is made of organic fiber-containing PPS resin. In addition, the angular position of the magnetic head 49 shown in FIG. 5 is called the 1st angular position of this magnetic head, and the position rotated 180 degrees from the 1st angular position with the 2nd angular position of this magnetic head is shown. Free rotation between them.

The fan-shaped gear 59 is disposed at the position where the slide member 56 is fitted together with the bearing member 57, and the rotation is freely attached to the front end portion of the bearing member 57 at an important part of the fan. . However, the long hole 56a in which the coupling portion is loosely inserted in the slide member 56 extends forward and backward so that the coupling portion between the fan-shaped gear 59 and the bearing member 57 does not interfere with the reciprocation of the slide member 56. It is installed. The fan-shaped gear 59 is click-pressed by the coil spring 60. A pin 59a protrudes from the right end surface of the fan-shaped gear 59, and this pin is conically joined to the slide member 56. That is, the fan gear 59 swings in accordance with the reciprocation of the slide member 56. The gear part of the fan-shaped gear 59 is engaged with the gear 61 fixed to the coaxial shaft part of the rotating shaft of the magnetic head 49.

The second gear 34, the movable plate 52, the lever D 53, the spring 54, the slide member 56, the bearing member 57, the fan gear 59, and the coil spring 60. And a head rotating mechanism for rotationally driving the magnetic head 49 by the gear 61 and the peripheral element members related thereto. The head rotating mechanism and the head-to-head driving mechanism described above are collectively referred to as a control mechanism. That is, the head stand 47 is reciprocated by this control mechanism, and the magnetic head 49 is rotated. In addition, as understood from the description up to this point, the first gear 33 rotates 360 ° so that the headrest 47 performs one movement of the reciprocating and double acting, and the second gear 34 rotates 180 °. The magnetic head 49 is rotated 180 degrees.

Here, a description will be given of the adidas adjusting means for angle control with the magnetic head 49.

For example, as shown in FIG. 5 and FIG. 9, on the head rest 47, a restricting member 64 extending in the front-rear direction is fixed to surround the magnetic head 49. As shown in FIG. The restricting member 64 is made of a steel sheet and has flexibility.

모양의 하변부가 자기헤드(49)의 외주부에 돌출 설치된 돌기(49a)에 걸어맞춤으로써 자기헤드(49)의 회전을 규제하도록 되어 있다.The restricting member 64 is formed symmetrically in the front-rear direction, and is fixed to the head rest 47 at the center portion thereof, and the front and rear ends of the front and rear ends extending in a direction insulated from each other with the center portion as the center are separated from the magnetic head ( It can be fitted to the outer circumference of 49). More specifically, the front and rear ends of the restricting member 64 are positioned so as to surround the magnetic head 49 front and rear, and both ends are formed to be bent in shape.

The lower side of the shape is engaged with the projection 49a protruding from the outer circumference of the magnetic head 49 so as to restrict the rotation of the magnetic head 49.

In addition, an opening 64a is provided on the upper surface of the restricting member 64 so that the projection 49a of the magnetic head does not touch the restricting member 64 when the magnetic head 49 rotates. On both front and rear ends of the restricting member 64, a pair of screws 65 screwed to the head rest 47 are engaged at their necks. In addition, a pair of springs 66 are provided between the lower surfaces of the front and rear ends of the restricting member 64 and the head rest 47 to impart an upward biasing force to the front and rear ends. In FIG. 5, only one spring 66 is displayed. Positioning means for positioning the front and rear ends of the restricting member 64 by these screws 65 and the spring 66 is configured. In addition, the positioning means and the restricting member 64 constitute a Adimas adjusting means. In other words, the angle setting at the two angular positions of the magnetic head 49 can be performed separately by tightening or slowing down the pair of screws 65.

In addition, the restricting member 64 is divided into two members at its central portion, and each of them is fixed to a head beam 47 with respect to the head rest 47 directly above the magnetic head 49. Even if it is set as above, the same effect is acquired. However, the number of parts is reduced and the number of assembly plants is reduced by contributing to the single member of the front and rear symmetrical shape, contributing to cost reduction.

The description is reversed, but, for example, as shown in FIG. 18, the first gear 33 has two missing teeth 33c and 33d symmetrically with respect to the partial teeth 33b having about three teeth. It is installed. When the first gear 33 is in the stopped state before its operation, the missing tooth portion 33c corresponds to the gear 16 (part of the gear transmission mechanism 20). It is regulated that the partial tooth part 33b is bitten by the gear 16. On the other hand, two missing teeth 34c and 34c are formed in the second gear 34 at a pitch of 180 degrees, and the missing teeth 34c are gears 18 when the second gear is in the stopped state before operation. ) And a part of gear transmission mechanism 20, and rotation of this 2nd gear is restrict | limited so that a toothed part may not be rolled up by gear 18 as mentioned later.

Next, when the first gear 33 and the second gear 34 rotate, the second gear 34 is engaged with the gear 18 after the first gear 33 is engaged with the gear 16. The trigger means will be described.

As evident in FIG. 4, the rear end of the control panel 39 is engaged with the stop pins 34a and 34b of the second gear 34 when the control panel is not in its reversing position (rightward limit position). A restricting portion 39d for restricting the rotation of the two gears is formed. As shown in FIG. 2, FIG. 4, and FIG. 17, a forbidden lever 69 is disposed on the left side of the control panel 39, and at the lower end thereof, fluctuations are caused in the rear bent portion 3a of the chassis 3. FIG. It is attached freely. The prohibition lever 69 is formed with an engagement recess 69a that can engage with the pin 39e protruding from the front surface of the central portion of the control panel 39. The forbidden lever 69 is applied with a force in the clockwise direction in FIG. 17 by the coil spring 70. The prohibition of prohibiting double acting (movement to the right) of the control panel when the control panel 39 is swung by the prohibition lever 69 and the coil spring 70 to reach its highest moving position (left movement limit position). Means are constructed. On the other hand, as is particularly evident in Fig. 7, the outer periphery of the first gear 33 is provided with a projection 33f that can engage the engaging projection 69b formed on the forbidden lever 69. That is, at the start of the first gear 33, the projection 33f of the first gear is engaged with the engaging projection 69b so that the forbidden lever 69 swings in the counterclockwise direction in FIG. 17, The double acting ban state of the control panel 39 in the highest Wangdong position is released.

Of the above-described prohibition means (prohibited lever 69, etc.), the control panel 39, the biasing means for applying the force in the double-acting direction (right) to the control panel 39, and the first gear 33 Coil spring 35 as a biasing means for applying the first gear in a direction in which the partial tooth portion 33b is engaged with the gear 16 (part of the gear transmission mechanism 20), and the second gear 34. As shown in FIG. Click member 51a and spring member 51a as a biasing means for applying a force to the second gear in the direction in which the teeth thereof engage with gear 18 (part of gear transmission mechanism 20), and peripheral elements associated therewith. When the first gear 33 and the second gear 34 start to rotate by the member, the first gear 33 is engaged with the gear 16 and then the second gear 34 is engaged with the gear 18. The trigger means is configured. As shown in FIGS. 2, 7, 9 and 18, a triangular star art trigger lever 73 is attached to the front of the center portion of the sub-sash A 11 freely rotating at the center portion thereof. It is. As is apparent from Figs. 7 and 18, one end 73a of the star art trigger lever 73 is bent at a right angle to the rear, and this bent portion can be engaged with the first gear 33. It is. More specifically, the pin 33a protruding from the rear surface of the first gear 33 penetrates through the first gear and protrudes by a predetermined amount on the front surface of the first gear. One end portion 73a is engaged with the protruding portion of the front surface, thereby restricting the rotation of the first gear 33. A second end portion formed on the star art trigger lever 73 and extending from side to side 73b is engaged with the left end of the lever A 12 from the bottom end of this left end. That is, the second end portion 73b of the star art trigger lever 73 is engaged with the end detection lever 10 through the lever A 12, and the star detection lever 10 operates upward so that the star is triggered upward. The art trigger lever 73 is rotated in the clockwise direction in FIG. 18, and the rotation regulation state of the first gear 33 is released. The star art trigger lever 73 has a third end 73c extending downward, and the third end is engaged with the left end of the magnetic head switching command rod 75 shown in FIG. The magnetic head switching command rod 75 is freely attached to the lower surface of the chassis 3 in the left-right direction, is made of steel sheet, and is formed in an L-shape as a whole. In other words, the magnetic head switching command rod 75 is moved to the left so that the star art trigger lever 73 rotates clockwise in FIG. Similarly, as shown in FIG. 10, in the vicinity of the head switching command rod 75, a coil spring 6 which imparts a bias force to the right to the third end 73c of the star art trigger lever 73 is provided. Excreted. As shown in FIG. 2, FIG. 3, and FIG. 17, the electromagnetic solenoid 77 extends from side to side in the vicinity of the motor 24, and is fixed on the chassis 3. As shown in FIG. The movable path 2 (77a) of the electromagnetic solenoid 77 protrudes to the right with respect to the solenoid main body, and the pin 77b extending in an up-down direction is fitted to the front-end | tip of this movable rod. The lower end of the pin 77b is loosely fitted in the long hole 3c formed to extend left and right on the main surface of the chassis 3 and is engaged with the right end of the magnetic head switching command rod 75. That is, as the movable rod 77a of the solenoid 77 is attracted, the magnetic head switching command rod 75 moves to the left (thus, the star art trigger lever 73 rotates clockwise in FIG. 18). It is supposed to. Moreover, as shown in FIG. 1, the operation switch group 79 is arrange | positioned at the right side of the opening part 2a as the front surface of the housing | casing 2, and one switch of this operation switch group is the said solenoid 77 It is a switch command switch to operate the controller. As shown in Figs. 2, 4, 10 and 17, the front surface of the rear bend portion 3a of the chassis 3 to which the control panel 39 is attached is in the same direction as the control panel, i.e., left to right. In the movement, the movement member 81 is attached freely. The moving member 81 is disposed at a position fitted by the bent portion 3a and the control panel 39. A projection 81a is provided at the upper end of the left end of the moving member 81, and the pin 33a of the first gear 33 is engaged with the right edge of the projection. That is, the moving member 81 moves to the left side together with the control panel 39 as the first gear 33 rotates. The right end of the moving member 81 is connected to a coil spring 82 for imparting a biasing force to the right side of the moving member.

As is particularly evident in FIG. 3, the right side of the moving member 81 is provided with a lever E 83 formed in a T-shape, and at about its center part a rotation in the rear bend portion 3a of the chassis 3. It is attached freely. The first end 83a, which is formed at the lever E 83 and extends downward, is connected to the rear end of the moving member 81 via a coil spring 84. That is, the lever E 83 rotates clockwise in FIG. 17 by moving the moving member 81 to the left. The front end of the second end portion 83b formed on the lever E 83 and extending to the left side is provided with a pin 83c extending forward, and the pin is a convex portion 39g formed at the rear end of the control panel 39. ) And the recessed part 39h, respectively. When the pin 83c is engaged with the recessed part 39h, the control panel 39 moves to the most-locomotion position (rightward movement limit) position of this control panel. Can be moved, and when the pin 83c is engaged with the convex portion 39q, the return of the control panel 39 to this lowest moving position is restricted. As described above, when the control panel 39 is not in the retracted position, the restricting portion 39d formed on the control panel is engaged with the stop pins 34a and 34d of the second gear 34 to regulate the rotation of the second gear. do.

As shown in Figs. 2, 3, 9 and 17, above the solenoid 77, another solenoid 86 is arranged in parallel with the solenoid 77, and the chassis (3) It is fixed on the top. The movable rod 86a of the electromagnetic solenoid 86 projects to the left side of the solenoid main body, and a pin 86b extending in the front-rear direction is fitted to the front end of the movable rod. The pin 86b is formed in the lever E 83, and is conically joined to the front-end | tip of the 3rd end part 83d extended upward. The pin 83c of the lever E 83 is engaged with the rear convex portion 39g of the control panel 39 when the movable rod 86a is in its protruding position (position shown in FIG. 17). The electronic solenoid 86 is operated by operating the key of the vehicle on which the cassette deck is mounted. When the key is in the on state, the movable rod 86a of the electronic solenoid 86 is moved to the left side of the moving member 81. The pin 83c of the lever E 83 is engaged with the rear end recess 39h of the control panel 39 because the pin 83c of the lever E 83 is fixed at the pulled in position along with the movement. In addition, when the key is in the off state, the movable spring 86a is pulled out by the coil spring 82 which applies the force to the right side of the movable member 81 and the biasing force, and thus the pin 83c of the lever E 83. ) Is engaged with the rear block portion 39g of the control panel 39.

Control panel 39 when the power is cut off by the movable member 81, coil spring 82, lever E 83, coil spring 84, electromagnetic solenoid 86, and peripheral elements associated therewith The prohibition release means is configured to prohibit the return to the most reversible movement position (the rightward movement limit position) and release the forbidden when the power is turned on.

Next, the tape transfer direction switching means for switching the transfer direction of the magnetic tape will be described.

As shown in FIG. 2, FIG. 3, and FIG. 9, the shaft member 30a of the support lever 30 which holds the idler gear 28 freely to rotate is a capstan. In addition, as shown in FIG. 10, the biaxial member 30a also serves as the central axis of rotation of the flywheel 27. As shown in FIG. On the other hand, as is particularly evident in FIGS. 3 and 5, a pair of support shafts 89 protruding upward are provided on the chassis 3 and in the vicinity of the capstan 30a. An arm member 91 having a freely rotatable pinch roller 90 attached to its free end is freely rotatable. The pair of pinch rollers 90 are free to detach and attach to the capstan 30a, respectively. A pin 91a penetrating the arm member in the vertical direction is fixed to the free end of the arm member 91, and a spring for adjusting the adimus of the magnetic head 49 is attached to the lower edge of the left edge of the pin. 66) (see, eg, FIG. 5) is engaged. The arm member 91 is urged by the spring 66 in the direction in which the pinch roller 90 approaches the capstan 30a.

The tape corresponding to the two rotational angle positions of the magnetic head 49 by the capstan 30a, the pinch roller 90, the reel unit 5, the idler gear 28, and the peripheral element associated therewith. The tape conveyance direction switching means which determines a conveyance direction is comprised.

The upper end of each pin 91a provided at the front end of the arm member 91 can be engaged with the front end and the rear end of the slide member 56, respectively. More specifically, the front and rear ends of the slide member 56 are each provided with two cutouts 56c extending in the front-rear direction and facing each other with the open ends, and the pins of the arm member 91 91a) is provided such that either one of them can be selectively engaged with the reciprocating motion of the slide member 56 in the cutout 56c. As an open end of each cutout 56c, a tapered portion 56d is formed at the front edge thereof, and the pin 91a is guided smoothly into the cutout 56c by the tapered portion 56d. As the pin 91a is engaged with the notch 56c, the arm member 91 is rotated to the left by a predetermined amount so that the pinch roller 90 is separated from the capstan 30a. That is, the pair of pinch rollers 90 may alternatively be separated from the capstan 30a by the reciprocating motion of the slide member 56, which is a constituent member of the head rotating mechanism.

As is particularly evident in FIG. 5, mountain-shaped protrusions 47a are formed at both left and right ends of the head rest 47 holding the slide member 56 so that the peaks face each other. Moreover, the recessed part 47b is formed in the left side of the processus | protrusion 47a continuously in this processus | protrusion. These protrusions 47a and recesses 47b are engaged with the pins 30d protruding at one end of the swinging lever of the support lever 30 shown in FIG. 3, for example, when the head rest 47 moves to the right. When the projection 47a formed in the shape of a mountain is engaged with the pin 30d, the support lever 30 has the idler gear 28 attached to the support lever as the rail unit 5 and the double gear. The support lever is in a position where the idler 28 is engaged with the double gear 5f when the swing 47 is swung in the direction away from 5f and the recess 47b is engaged with the pin 30d following the protrusion 47a. (30) is supposed to return.

On the other hand, the front and rear ends of the slide member 56 are also engaged with one of the pins 30d of the pair of front and rear support levers 30, respectively, when the head rest 47 moves to the right. A projection 56e for restricting entry into the recess 47b of the 47 is formed. However, each of the projections 56e is engaged with only one of the pair of pins 30d in accordance with the reciprocation and double acting of the slide member 56. That is, the pair of idler gears 28 are configured to be separated from the rail unit by the reciprocating motion of the slide member 56 which is a part of the head rotating mechanism.

Next, a mechanism for loading the cassette half is described.

As shown in FIG. 2, FIG. 6, and FIG. 12 to FIG. 14, the subsash B 95 is fixedly installed on the upper surface of the right end of the chassis 3. A rocking member A 96 extending in the lateral direction is disposed on the chassis 3, and the support protrusion 3d provided at the left rear end of the sub chassis B 95 and the chassis 3 is disposed at the rear end thereof. The swing is attached freely. At the free end of the swinging member A 96, that is, at the front end, a cassette holder 98 for retaining the cassette half is freely attached to the center portion in the front-rear direction thereof. Also, for example, the position of the cassette holder 98 shown in FIG. 5 is referred to as the rising position of this cassette holder. The cassette half is inserted into the cassette holder 98 at this position from the direction of the arrow S and is retained in this cassette holder. From this state, the swinging member 96 swings downward by a predetermined angle, and the position of the cassette holder 98 when the cassette half is held in the cassette holder 98 is positioned at the playing position. The drop position of the holder is called. The cassette holder 98 is movable between this dropping position and the rising position.

The lower surface of the cassette holder 98 is composed of two members, an upper surface member 99 and a rear member 100, and a movable member 101 which can be engaged with the cassette half is inserted and discharged in the cassette half. That is, the movement in the front and rear direction is freely attached. A pin 100a protrudes from the rear surface of the rear member 100, and the pin is fitted so as to be able to slide freely in the long hole 95a formed by extending in the front and rear direction on the subsash B 95. On the other hand, the lever F 102 is attached to the center lower end of the sub chassis 95 so that it can rock freely at the lower end part, and the upper end part of this lever F is conical-joined to the pin 100a. The coil spring 103 which applies the lever F 102 to the lever F 102 in the clockwise direction in FIG. 13 and thus gives the moving member 101 a cassette half discharge direction, that is, a biasing force to the front. Is connected. A recess 100b recessed downward is formed at the front end of the right surface member 100, and the right surface member 100 when the cassette half is inserted is moved backward, so that the cassette holder 98 swings. The central axis 98a falls into this recess 100b, and this cassette holder moves to the dropping position. Further, a coil spring 104 for connecting the rocking member A 96 in the clockwise direction in FIG. 13 is connected to the right end of the rocking member A 96. Further, as the moving member 101 moves in the cassette half insertion direction (rear), the cassette holder 98 is applied by the coil spring 103 toward the dropping position.

As is clear from Figs. 12 and 14, the upper surface 99 of the movable member 101 has projections 99c opposed to the rail holes 106 of the cassette lower half, and the projections 99c. A spring member 99d is provided to apply a force to the cassette lower half so as to project into the rail hole 106. In addition, the protrusion 99C is formed integrally with the upper surface member 99 by punching and the like. Thus, by integrally forming the projection 99c on the upper surface member 99, it is not necessary to attach a special component to the upper surface member 99 in order to install this projection, and the number of parts for construction It is being cut down and cost reduction is planned. The upper member 99 is further provided with another projection 99e which engages with the cassette lower half in the vicinity of the rail hole 106. Similarly to the projection 99c, the projection 99e is formed integrally with the upper surface member 99 by a punching process or the like, thereby reducing the price. Moreover, the projection 99e is engaged with the recessed part 107 called rear in the label formed in the cassette half. Thus, by engaging the protrusion 99e with the recessed part provided in the cassette half, the engagement state with respect to the cassette half of the protrusion 99e becomes strong. In the cassette deck, the cassette half is inserted into the cassette holder 98 described above along its longitudinal direction. In addition, a control mechanism for reciprocating the headrest 47 and rotating the magnetic head 49 is disposed near the deepest portion of the cassette holder 98.

Next, a mechanism for performing the FF operation (tape rapid feeding operation) and the REW operation (tape rewinding operation) will be described.

As shown in Figs. 2, 3, 9, and 16, the left end of the chassis 3 is bent to extend upward, and the curved portion 3f also has Figs. The illustrated subchassis C 111 is fixed. A pair of long operation levers 113 and 114 extending in the front-rear direction and superimposed up and down are attached to the sub chassis C 111 freely in reciprocating direction. Each of the long operation levers and the front end portion, that is, the operation end portions, are separated from the left and right by a predetermined amount, and each operation end portion is provided with operation buttons 115 and 116 (first shown) provided on the front surface of the housing 2. . The long operation lever 113 disposed at the bottom is for the FF operation by its movement, that is, the rearward movement, and the long operation lever 114 installed at the top is for the REW operation at the operation. Each of these long operation levers 113 and 114 is disposed above the magnetic head 49. In addition, the two long operation levers 113 and 114 are biased forward by coil springs 118 and 119, respectively.

As is particularly evident in FIGS. 7 and 15, the head stage is moved to the upper end of the long pin 121 protruding from the upper left end of the head rest 47 to the rear end faces of the long operating levers 113 and 114. The tapered portions 113a and 114a that can be engaged with each other are formed. That is, when the head stand 47 is moved to the right, by pushing any of these long operating levers 113 and 114, the head stand 47 is moved to the left by a predetermined amount, whereby the magnetic head 49 is magnetic tape. It can be isolated from. In addition, when the head rest 47 is moved to the left by a predetermined amount by the operation of the long operation lever, the support lever 30 in which the protrusion 47a formed on the head rest 47 holds the idler gear 28 is provided. Is engaged with the pin 30d of the idler gear, whereby the idler gear 28 is separated from the reel unit 5 and the double gear 5f. In addition, the front and rear of the horse is reversed, for example, as shown in Figs. 3 and 9, a pair of click members 123 are provided on the chassis 3 to prevent reverse rotation of the reel unit (5). . When the head stand 47 is moved, the right end of the head stand 47 is engaged with the click member 123 to push it in, and the reverse unit prevents reverse rotation of the rail unit 5 by this click member. have.

As shown in FIG. 2, FIG. 3 and FIG. 16, the plate 124 is moved forward and backward on the right side as the rear end of the bent portion 3f formed at the left end of the chassis 3, as shown in FIGS. The movement is freely attached. Coil springs 125 that impart a biasing force to the plate forward are connected to the upper protrusion 124a of the plate 124. A lever 126 formed in a T-shape is rotatably attached to the front end of the plate 124 at its central portion. In particular, as is apparent from FIG. 16, the first end portion 126a formed at the lever H 126 extending downward and the protrusion 113c extending downward and protruding downward from the long operation lever 113 described above. The back edge of the abuts. In addition, the front edge of the second end portion 126b formed on the lever H 126 extending upwards is brought into contact with the rear edge of the protrusion 114c extending to the left of the other long operation lever 114 and provided to protrude. have. That is, the lever H 126 rotates counterclockwise in FIG. 16 by pushing the long operation levers 113 and 114, respectively.

In the front of the plate 124, a lever I 129 formed in a substantially <-shape is disposed, and rotation is freely attached to the left bent portion 3f of the chassis 3 at the center bent portion thereof. A pin 129b protrudes from the front end of the first end 129a which is formed in the lever I 129 and extends rearward, and the pin 129b is formed in the lever H 126 and extends forward. It is fitted to slide freely in the long hole 126d formed in the three end portions 126c.

In addition, the lever I 129 and the second end 129c extend downward.

As shown in FIG. 2, FIG. 3, FIG. 10 and FIG. 16, the swing lever 130 extends to the left and right directions to the position fitted to the pair of reel units 5 and flywheels 27, respectively. It is arrange | positioned, and the oscillation is attached freely to the chassis 3 via the pin 130a at the substantially center part. The left end of the swing lever 130 is conically joined to the front end of the second end 129c of the lever I 129. In addition, a gear transmission mechanism 135 composed of three gears 132, 133, and 134 engaged in series is provided on the lower surface of the right end of the swing lever 130. The gear 132, which is the first gear of the gear transmission mechanism, can be engaged with each gear portion 27a of the pair of flywheels 27, and the gear 134, which is the final gear, is the double gear of the reel unit 5. It can be engaged with the small diameter gear part formed in 5f). That is, as the long operating levers 113 and 114 are pushed, the swing lever 130 swings backwards and forwards through the lever 126, whereby the rear unit 5 disposed rearwards and forwards is alternatively selected. It can be rotated at high speed.

As shown in Figs. 2, 7, 15 and 16, on the subsash 111 which holds the long operating levers 113 and 114, the two long operating levers are arranged in parallel with the two long operating levers. An intermediate lever 138 is provided which is free to reciprocate in the moving direction (rear direction) of the operation lever. The intermediate lever 138 is connected to a coil spring 139 for imparting a biasing force to the intermediate lever in the forward direction. As is particularly apparent in FIG. 15, a pin 138a protrudes from a lower surface of the rear end of the intermediate lever 138, and the pin is formed to extend in the front-rear direction to the long operating levers 113 and 114 in correspondence with the pin. It is engaged to 140 to slide freely. At the right end of the central portion of the long hole 140, a recess 140a into which the pin 138a can be inserted is formed. Here, the intermediate lever 138 is able to oscillate by a predetermined angle about the support shaft 138b at the front end thereof. In addition, the coil spring 139 for applying the force toward the middle lever 138 forward is inclined from the rear to the front to the right, whereby the intermediate lever 138 is centered on the support shaft 138b. The force is applied also in the counterclockwise direction in FIG. That is, when the two long operating levers 114 and 113 are simultaneously moved (moving backward), the pin 138a of the intermediate lever 138 is inserted into the recess 140a of the long hole 140, thereby causing the intermediate lever. 138 is configured to move backwards. However, if only one of the pair of long operating levers 113 and 114 is moved together, the rear right edge 140b of the long hole 140 formed of the other long operating lever still contacts the pin 138a. Therefore, the moving (moving backward) of the intermediate lever 138 is not made. In addition, although not mentioned in detail, when the long operation lever of either the FF acting long operation lever 113 or the REW acting long operating lever 114 is swung, the mechanism which locks this in a moving position is provided. have. The lock mechanism locks the long operation lever to the king position when the other long operation lever is moved, and unlocks the one long operation lever. When either of the long control levers 113 and 114 is pushed, the lever J 142 provided at the rear of the two long control levers is swung in the clockwise direction in FIG. 15 so that the mute switch 143 is moved. It is supposed to work.

For example, as evident in FIGS. 2 and 7, a pin 138d protrudes from the upper surface of the rear end of the intermediate lever 138, and the pin is formed of the rocking member 96 (e.g., shown in FIG. 6). It is directly engaged with the left end 96a. This intermediate lever 138 is for moving the cassette holder 98 in the above-mentioned falling position by pushing the swinging member B6 backward by moving.

Next, various switches provided other than the mute switch 143 and the arrangement thereof will be described.

As is apparent from FIGS. 2 and 6, a bracket 146 is attached to the right end surface of the sub chassis B 95, and two switches 147 and 148 are attached to the bracket. The switch 147 is for switching the power supply to the cassette deck and the tuner disposed in the vicinity of the cassette deck. In addition, the switch 148 is for operating the motor 24. Both switches 147 and 148 are mechanically operated when the cassette half is inserted into the cassette holder 98 together.

As shown in FIG. 2, FIG. 7 and FIG. 18, the switch 149 for switching FF and REW is fixedly installed in the front surface of the left end part of the subsash 11. As shown in FIG. This switch 149 operates by engaging the movable plate 52 attached to this subchassis A. As shown in FIG. In addition, as shown in FIG. 15, a switch 150 is fixed on the subchassis 111 to cut off the power supply to the cassette deck, and the intermediate lever 138 is moved to the rear (backward). It works when it is moved.

The operation of the cassette deck having the above-described configuration will be briefly described in accordance with the operation procedure with reference to FIGS. 19 to 26. FIG. First, the cassette half 155 (shown in FIG. 19) is inserted from the opening 2a of the housing 2 shown in FIG. 1, and as shown in FIGS. 19 to 21, the cassette half In the cassette holder 98. As shown in FIG. 20, when the cassette half 155 is inserted into the cassette holder 98, the right surface member 100 is moved backward, whereby the pivot center axis 98a of the cassette holder 98 is moved. ) Falls into the concave portion 100 of the right surface member 100, and the cassette holder is moved to the lowered position. Thus, the cassette half is set to the playing position. In accordance with this cassette half insertion operation, for example, the switches 147 and 148 shown in FIG. 6 are operated to supply power to the cassette deck, and the motor 24 starts to rotate. When the motor 24 rotates, as shown in FIG. 10, the pulley 24a moves in the direction of the arrow M, and the pulley 23 moves in the direction of the arrow N, and a pair of front and rear flywheels are shown. Are rotated in the directions of arrows O and P, respectively. Thus, the pair of reel units 5 respectively start to rotate in the directions of the arrows Q and R (Fig. 10) through the pair of idler gears 28, respectively. In this way, since the pair of reel units 5 rotate in opposite directions to each other, the relaxed portions of the magnetic tape in the cassette half 155 can be wound. When the relaxed portion of the magnetic tape is wound so that a predetermined tension is applied to the magnetic tape, all members except the double gear 5f among the constituent members of the reel unit 5 shown in FIG. And the double gear 5f continues the process through the felt plate 5h with respect to these fixed member groups. Therefore, the magnetic tape is not conveyed in the state where the tension is applied. On the other hand, for example, the end detection gear 14 shown in FIGS. 7 and 18 is rotated counterclockwise in FIG. 18 through the gear transmission mechanism 20 by the rotation of the motor 24. . Accordingly, the pin 10b protruding from the end detection lever 10 can be moved to the top of the mountain-shaped protrusion 14b of the end detection gear in accordance with the rotation of the end detection gear 14. Here, as apparent from the above, the arm 5i of each real unit 5 is stopped.

Therefore, the intermediate lever 7 does not operate, and the pin 10b of the end detection lever 10 does not slide along the mountain projection 14b to continue the movement. Thus, the pin 10b of the end detection lever 10 stops at the top position of the mountain-shaped protrusion 14b, whereby the projection 14c of the end detection gear 14 is engaged with the pin 10b. Accordingly, the end detection lever 10 moves upward, and the star art trigger lever 73 rotates clockwise in FIG. 18 through the lever 12. Thus, as the pin 33a is engaged with one end of the star art trigger lever B73, the first gear 33 whose rotation is restricted is rotatable, and the force of the coil spring 35 is applied. This rotates in the clockwise direction in FIG. Thus, the partial teeth 33b of the first gear 33 mesh with the gear 16, and the first gear starts to rotate. By the rotation of the first gear 33, the control panel 39 shown in FIG. 17 and the like moves to the left. Therefore, the head rest 47 moves to the right as shown in FIG. 49 abuts on the magnetic tape. In addition, the control panel 39 that has reached the most dongdong position (the leftward moving limit position) has its double acting motion due to the engaging recess 69a of the forbidden lever 69 being engaged with the pin 39e protruding from the control panel. Movement to the right) is prohibited. In accordance with the rotation of the first gear 33, the movable member 81 shown in FIG. 17 and the like is also moved to the left as in FIG. Accordingly, the lever E 83 rotates clockwise as shown in FIG. 23, and the movable rod 86a of the electromagnetic solenoid 86, which is already in an ON state, is pushed in. By this operation, the pin 83c of the lever E 83 is engaged with the concave portion 39h formed at the right end of the control panel 39, and therefore the lowest moving position of the control panel 39 (towards the right side). Movement to the limit position). Further, as the pin 39e of the control panel 39 enters the engaging recess 69a of the forbidden lever 69, the forbidden lever 69 is rotated by a predetermined clockwise direction as shown in FIG. Then, the mute switch 143 whose upper end portion is turned on via the lever J 142 (see Fig. 7, for example) is turned off.

On the other hand, as shown in FIG. 22, the front idler gear is separated from the double gear 5f of the front rail unit 5 as the head unit 47 moves to the right side, and the rear rail unit 5 is rearward. ) Will only rotate. In addition, this operation is based on the interaction between the protrusion 47a and the concave portion 47b formed on the head rest 47 and the protrusion 56e provided on the slide member 56. Not specified. Moreover, as shown in FIG. 22, with the right side movement of the head stand 47, the rear pinch roller 90 comes in contact with the capstan 30a, ie, the front pinch roller 90 It is kept in the state separated from the corresponding capstan. This is because the pin 91a protruding from the arm member 91 which supports the front pinch roller 90 is fitted in the notch 56c of the slide member 56. As shown in FIG. Similarly, as shown in FIG. 22, the pair of click members 123 engaged with the reel unit 5 by the right movement of the head rest 47 are disengaged from the reel unit.

Thus, tape travel starts on the FWD side, and playback on the FWD side is performed.

Next, the operation of switching from the playback on the FWD side to the playback on the REW side will be described.

When the switch for switching the tape running direction is pressed, the electromagnetic solenoid 77 is turned on, and the movable rod 77a of this electromagnetic solenoid is pulled out. For this reason, the star art trigger lever 73 rotates in the clockwise direction in FIG. 18 via the magnetic head switching command rod 75. As a result, the first gear 33 whose rotation is restricted by the star art trigger lever is rotatable, and is rotated clockwise in FIG. 18 by the force of the coil spring 35. Thus, the partial teeth 33b of the first gear 33 mesh with the gear 16, and the first gear starts to rotate. As soon as the first cogwheel 33 starts to rotate, the projection 33f protruding from the first gear is engaged with the engaging projection 69b of the prohibition lever 69 (see also Fig. 17), and this prohibition lever Is rotated counterclockwise in FIG. Then, the engagement state between the engaging recess portion 69a of this prohibition lever and the pin 39e of the control panel 39 is released, and the control panel 39 is instantaneously moved to the maximum retracted position by the force of the coil spring 40 ( Return to the right limit position). The headrest 47 moves to the left by the return of the control panel 39 to this lowest moving position, and the magnetic head 49 is separated from the magnetic tape.

When the control panel 39 is in the longest moving position (left movement limit position), the stop pin 34a is engaged with the restricting portion 39d (for example, FIG. 4) formed in the control panel, and the second gear ( The rotation of 34 is regulated. This restriction is released by the return of the control panel 39 to the above-mentioned shortest moving position. For example, by the action of the click member 51a and the spring member 51b shown in FIG. It rotates clockwise in FIG. Thus, the toothed portion of the second gear 34 meshes with the gear 18 so that the second gear starts to rotate. By the rotation of the second gear 34, the stop pin 34a protruding from the second gear is engaged with the click portion 52a of the moving plate 52, so that the moving plate moves to the left. The magnetic head 49 connected to the plate is rotated 180 ° towards the REV. In addition, the switch 149 is switched from the FWD side to the REV side by the left side movement of the movable plate 51.

By the rotation of the second gear 34, the stop pin 34a of the second gear is engaged with the projection 39c (see FIG. 17, etc.) formed in the control panel 39, and this control panel is the stop pin. Is moved left by a predetermined distance. When the second gear 34 completes the 180 ° rotation, the stop pin 34a is formed to be separated from the protrusion 39c of the control panel 39. Then, the pin 33a of the first gear 33 is engaged with the projection 39a of the control panel 39, so that the control panel 39 is moved to the highest moving position (left moving limit position), as described above. It is locked by the prohibition lever 69. The headrest 47 moves to the right again by the tum of the control panel 39, and the magnetic head 49 abuts on the magnetic tape. The mute switch 143 is also turned off as described above.

In addition, the slide member 56 is moved forward by the left side movement of the movable plate 52 so that the rear idler gear 28 is separated from the rear unit 5 at the same time as the right side movement of the headrest 47. Further, the front idler gear 28 is fastened to the rail unit 5 so that only the front rail unit 5 starts rotation. Moreover, the front pinch roller 90 abuts the capstan 30a, and the rear pinch roller 90 is retained in a state separated from the capstan 30a. Thus, the tape running direction is switched from the FWD side to the REV side.

In addition, for the operation of switching the tape running direction from the REV side to the FWD side, the stop pin 34b of the second gear 934 is engaged with the click portion 52b (FIG. 18) of the movable plate 52. Except for moving the moving plate to the right, the tape conveying direction switching operation from the FWD side to the REV side is substantially the same, and thus will not be described.

Next, the operation of the mechanism for automatically switching the tape conveying direction will be described.

For example, when the tape running to the FWD ends, a predetermined tension is applied to the magnetic tape of the end portion, so that all members except the double gear 5f among the constituent members of the reel unit 5 shown in FIG. It becomes a form fixed by reaction force. Therefore, only the double gear 5f continues to revolve through the felt plate 5h with respect to these fixed member groups. When the tape is running toward the FWD, the fixed member group is rotated except for the arm member 5i. The arm member 5i receives a biasing force due to the rotational force and forces the intermediate lever 7 in the counterclockwise direction in FIG. 22 through the flow lever 8. The end detection lever 10 having the rear end of the lever conically joined is applied with a rotational force in the counterclockwise direction as shown in FIG. 18, and the pin 10b protruding from the end detection lever has a mountain projecting portion of the end detection gear 14. The protrusion 14c and the pin 10b of the end detection gear do not engage with each other while sliding against the 14b.

By the way, when the group of members except the double gear 5f in the rail unit 5 is fixed at the same time as the tape stop, the force applied to the end detection lever 10 is extinguished and the projection of the end detection gear 14 is lost. 14c is engaged with the pin 10b of this end detection lever. Accordingly, the end detection lever 10 moves upward, and the star art trigger lever 73 rotates clockwise in FIG. 18 through the lever A 12. The tape running direction is switched by the same operation as that of the tape running direction from the FWD side to the REV side by pushing the above switch. Incidentally, automatic switching of the tape running direction from the REV side to the FWO side is performed in the same manner as the above operation, and thus will not be described.

Next, the FF operation (tape rapid feeding operation) and the REW operation (tape rewinding operation) will be described.

In the case of performing the FF operation, for example, during tape playback, as shown in FIGS. 24 and 25, the long operation lever 113 of the FF motion is pushed back to move. Then, the mute switch 143 is turned on through the lever J 142. Moreover, the long piece 121 which protruded to the left end part of the head stand 47 is pushed to the left by the taper part 113a of the long operation lever 113, and the head stand 47 is left by a predetermined part by this. The state where the magnetic head 49 and the magnetic tape come into contact with each other is relaxed.

As apparent from FIG. 25, the lever H 126, which is engaged with the projection 113c of the long operating lever, swings in the counterclockwise direction in FIG. 25 by the rearward movement of the long operating lever 113. As shown in FIG. do. Therefore, lever I 129 likewise swings clockwise in FIG. 25, whereby the swing lever 130 is centered around pin 130a as shown in FIG. Rotate counterclockwise in. Therefore, the first gear 132 of the gear transmission mechanism 135 provided on the swing lever meshes with the gear portion 27a of the flywheel 27 on the rear side, and the final gear 134 is the rear rail unit ( Engage with the small diameter gear portion of the double gear 5f of 5). On the other hand, the pair of idler gears 28 are separated from the rail unit 5 by the movement to the left side of the head rest 47 by pushing the long operating lever 113. Therefore, the rear rail unit 5 rotates at a high speed, and a tape rapid feed is performed.

In the case of the REW operation, this is achieved by pushing the long operation lever 114 of the REW operation. That is, the projection 114c of the long operation lever 114 is engaged with the second end 126b of the lever H 126, and this lever H is rotated in the clockwise direction in FIG. 132 and the final gear 134 mesh with the front flywheel 27 and the reel unit, respectively. In addition, the left side movement of the head stand 47 is achieved by engaging the tapered part 114a of the long operation lever 114 with the long pin 121 provided in the head stand 47. As shown in FIG.

When the tape reproduction is finished and the cassette half is ejected, the long operation lever 113 with the FF action and the long operation lever 114 with the REW action may be pushed simultaneously. By simultaneously pushing these two long operating levers, the intermediate lever 138 (e.g., FIG. 24) is moved backwards, so that the pin 138d protruding from the upper end of the rear end of the intermediate lever is the swinging member 96 (e.g. 6 degrees) to the left end.

Therefore, the cassette half is projected to the retrieval position by the listener by an operation opposite to that when the cassette half 155 is powered off. In addition, since the switch 150 shown in FIG. 24 also operates, for example, the solenoid 86 (see FIG. 23) is turned off, and the lever E 83 is closed by the action of the coil spring 82. FIG. It returns to the state of 17 degrees. Therefore, the pin 83 provided in the lever E 83 can engage with the convex portion 39g formed at the right end of the control panel 39. As a result, the return of the control panel 39 to the lowest moving position (rightward limit position) is prohibited. That is, the state where the stop pin 34a of the second gear 34 is engaged with the restricting member 39d of the control panel 39 is retained, and when the power is turned on again, the second gear 34 rotates. This prevents unnecessary switching in the tape travel direction.

As described above, the off operation of the electronic solenoid 86 is also performed when the key of the vehicle on which the cassette deck is mounted is turned off.

As described above, in the cassette deck according to the present invention, a head-to-vehicle moving mechanism including a first gear 33 for reciprocating the head-base 47 freely movable in a direction substantially perpendicular to the tape travel direction; And a head rotating mechanism including a second gear 34 for rotating the magnetic head 49 freely rotatable about an axis substantially parallel to a moving direction of the head stage. The first gear and the second gear. The rotational force is imparted by the rotational force applying means including a single drive source (the motor 24). Therefore, as compared with the cassette deck which performs the reciprocating operation for attaching and detaching the magnetic head to the magnetic tape and the rotating operation of the magnetic head for adjusting the forward and backward running of the magnetic tape by two or more driving sources, the entire cassette deck can be miniaturized and the cost can be reduced. It is easy to do it.

In addition, in the cassette deck according to the present invention, the rotational force applying means includes a gear transmission mechanism engaged with the first gear and the second gear, and after the first gear is engaged with the gear transmission mechanism, the second gear becomes the gear. Trigger means for engaging the delivery mechanism is provided. Therefore, the head is moved, the magnetic head rotates after the magnetic head is completely removed from the magnetic tape, and no damage or noise of the magnetic tape occurs.

In the cassette deck according to the present invention, the first gear rotates 360 ° so that the head stage operates as a reciprocating and double acting, while the second gear rotates 180 ° so that the magnetic head rotates 180 °. Therefore, the magnetic head can ensure the mutual timing of the reciprocating motion and the rotational motion reliably and most appropriately.

Claims (1)

Magnetic heads 47 which freely reciprocate in a direction substantially perpendicular to the tape running direction, and a magnetic body provided freely rotated between two angular positions about an axis substantially parallel to the head direction in the moving direction of the head object. Tape running direction switching means (30a, 90, 5, 28) for determining the tape running direction corresponding to the angular position of the head (49) and the magnetic head, and a first gear (33) for reciprocating the head stage by rotation. And a head mechanism including a head-to-head drive mechanism, a second gear 34 for rotating the magnetic head by rotation, and a gear transmission mechanism capable of engaging with the first and second gears. The first and second gears include rotational force applying mechanisms 20, 22, 23, and 25 for imparting rotational force from a single drive source 24, the second gear after the first gear is engaged with the gear transmission mechanism. Trigger means (69, 39, 40, 35, 51, 51a) are installed to engage the gear transmission mechanism, and the trigger means is freely provided between the reciprocating position and the reciprocating position so that the first gear A control panel provided with a regulating section for engaging with the second gear when being moved by the rotation and not in the least double-acting position; a biasing means for applying a force in the double direction to the control panel; Prohibiting means for prohibiting double acting of the control panel when reaching the highest thrust position, and releasing the prohibition by starting the first gear, and engaging the first and second gears with the gear transmission mechanism. And a biasing means for exerting a force in the direction of rotation, wherein the first gear rotates by 360 ° so that the head stage performs one movement of swinging and double acting, and the second gear rotates by 180 ° so that the Cassette deck, characterized in that the head is rotated 180 °.

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