JPH06176460A - Sliding mechanism for magnetic recording/reproducing device - Google Patents

Abstract

PURPOSE:To improve accuracy for deciding the position of a slide chassis on each movement stop location, to miniaturize the device, to make it light and to reduce its cost for the provision of the sliding mechanism for the magnetic recording/reproducing device. CONSTITUTION:On an 8-millimeter video, the pivot of a driving arm 91 for moving slide chassis 15 is inserted into the slide hole 77 of the slide chassis 15 erected on a base chassis 71 and shared by a supporting shaft 73 far supporting it freely movably. Further, the pivot of the releasing lever 184 of a ratchet brake 181 for controlling the rotation of the tape unwinding direction of a winding reel 141 is shared by another supporting shaft 75 of the base chassis 71.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic recording / reproducing apparatus, and more particularly to a slide mechanism of a magnetic recording / reproducing apparatus for slidably supporting a slide chassis supporting a cassette with respect to a base chassis attached to the main body of the apparatus.

[0002]

2. Description of the Related Art Among magnetic recording / reproducing devices that use a magnetic tape, there is a so-called 8 mm video. This 8
In millivideo, the slide chassis can store and hold a cassette case wound with magnetic tape.
Then, the slide chassis can be moved to the cassette attachment / detachment position where the slide mechanism protrudes outward from the video body by the built-in elevating mechanism to insert and remove the cassette case, and can be moved to the recording / reproducing position in the video body by the slide mechanism. At this recording / reproducing position, the magnetic tape in the cassette case can be pulled out and run to record or reproduce.

A loading mechanism for pulling a magnetic tape from the cassette case and winding the magnetic tape around the rotary head drum is mounted in the 8-mm video apparatus. This loading mechanism operates as the slide chassis moves to the recording / reproducing position to perform tape loading. At least a pair of guide posts are movably provided on both sides of the rotary head drum. The magnetic tape in the cassette case is pulled out and wound around the rotary head drum at a predetermined angle.

Then, when the cassette case with the magnetic tape is inserted into the cassette holder provided in the slide chassis in the eject (cassette attachment / detachment) state and lowered, the slide chassis is at the recording / reproducing position in the video main body. Slide to. At this time, at least a pair of guide posts are moved by the loading mechanism so that the magnetic tape in the cassette case is pulled out from the supply reel and wound around the rotary head drum at a predetermined angle. And
In this state, the recording or reproduction switch is turned on to run the magnetic tape, and recording or reproduction is performed.

[0005]

In the above-mentioned conventional magnetic recording / reproducing apparatus, as described above, the slide chassis has the cassette attaching / detaching position and the recording / reproducing position by the slide mechanism with respect to the base chassis in the video main body. It is possible to move between. In this slide mechanism, a pair of front and rear support shafts are provided upright on both sides of the base chassis, while long holes along the moving direction are formed on both sides of the slide chassis in the front and rear directions corresponding to the pair of support shafts. The slide chassis is slidable with respect to the base chassis by movably inserting the respective support shafts into the elongated holes. Then, the base end portion of the drive arm is pivotally supported by the base chassis, the front end portion is connected to the slide chassis, and the slide chassis can be moved by rotating the drive arm by a cam gear that can be driven and rotated.

Since such a magnetic recording / reproducing apparatus has various mechanisms built therein, the mechanism is complicated. Further, in order to reduce the size and weight of the apparatus itself, each member is made smaller and thinner. In addition, the layout takes into consideration such a situation. On the other hand, since the cassette for storing the magnetic tape is supported on the slide chassis, it must be supported so as to be freely movable with respect to the base chassis. The drive arm regulates the moving position of the slide chassis, and must be attached to the base chassis with high positional accuracy.

However, in the conventional magnetic recording / reproducing apparatus, each support shaft of the base chassis is simply inserted into the long hole of the slide chassis to support the slide chassis so that it can slide with respect to the base chassis. On the other hand, the drive arm is also pivotally supported on the base chassis by the support shaft, and since the slide chassis slide mechanism and the drive mechanism are attached to the base chassis independently of each other, the slide chassis (cassette) is stopped at each movement stop position. However, there is a problem that the positioning accuracy is insufficient and it is difficult to assemble each member to improve the positioning accuracy.

The present invention solves such a problem, and aims to improve the positioning accuracy of the slide chassis at the movement stop position, reduce the size and weight of the device, and reduce the cost. It is intended to provide a slide mechanism of.

[0009]

In a slide mechanism of a magnetic recording / reproducing apparatus of the present invention for achieving the above object, a supporting shaft is erected on both side portions of a base chassis mounted in the apparatus, The slide chassis supporting the cassette is formed with a long hole along the moving direction, and the support shaft is inserted into the long hole to slidably support the slide chassis on the base chassis. And a slide chassis are connected by a drive arm, and the slide chassis can be moved between a cassette attachment / detachment position and a recording / reproduction position by rotating the drive arm by a cam gear that can be driven and rotated. In the above, the base end portion of the drive arm is rotatably supported by one of the support shafts erected on the base chassis. The one in which the features.

Further, in the slide mechanism of the magnetic recording / reproducing apparatus of the present invention, the support shafts are provided upright on both sides of the base chassis mounted in the apparatus, while the slide chassis supporting the cassette is moved along the moving direction. A slide chassis is slidably supported by the base chassis by forming a long hole and inserting the support shaft into the long hole, and the base chassis and the slide chassis are connected by a drive arm to drive the slide chassis. By rotating the drive arm with a rotatable cam gear, the slide chassis can be moved between a cassette attaching / detaching position and a recording / reproducing position, and is locked to a rotating body on the magnetic tape take-up reel side at a predetermined time. And a magnetic recording reproducing device provided with a ratchet brake and its release lever for restricting rotation of the take-up reel in the tape winding direction. In the device, the base end of the drive arm is rotatably supported by one support shaft erected on the base chassis, and the base end of the release lever is rotatably supported by the other support shaft. It is characterized by having done.

[0011]

[Function] The rotation support shaft at the base end portion of the drive arm is also used as a support shaft for movably supporting the slide chassis erected on the base chassis, thereby positioning the slide chassis at each movement stop position. Can be performed with high accuracy, and the shared use can reduce the size and weight of the device and reduce the cost.

[0012]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a plan view of a slide chassis showing an eject (cassette attachment / detachment) state in an 8 mm video equipped with a slide mechanism of a magnetic recording / reproducing apparatus according to an embodiment of the present invention, and FIG. 2 shows a loading state. 3 is a plan view of the slide chassis, FIG. 3 is a plan view of the slide chassis showing the tape running state, FIG. 4 is a plan view of the base chassis showing the eject (cassette attachment / detachment) state in 8 mm video, and FIG. 5 is the base chassis showing the loading state. 6 is a plan view of the base chassis showing the tape running state in FIG. 6, FIG. 7 is a plan view showing the loading mechanism, FIG. 8 is a schematic showing the loading operation state, FIG. 9 is a perspective view of the cassette holder, and FIG. 10 is a cassette. Plan view of the holder, Figure 1
1 is a right side view of the cassette holder, FIG. 12 is a left side view of the cassette holder, FIGS. 13 and 14 are left and right side views of the cassette holder showing a cassette stored state, FIG. 15 is a front view of the cassette holder, FIG. 16 and FIG. 17 shows an operation explanation showing the positional relationship between the cassette case and the rotary head drum.

In this embodiment, an 8 mm video is used as the magnetic recording / reproducing apparatus equipped with the slide mechanism of the magnetic recording / reproducing apparatus. In addition, the cassette holder of the 8 mm video can be projected outward from the video main body by the elevating mechanism and can be slid to the recording / reproducing position with respect to the base chassis of the video main body by being supported by the slide chassis. There is. In this embodiment, the front side or the front side means the side where the cassette case is inserted into the cassette holder, and the rear side or the rear side means the opposite side.

First, the cassette holder and its elevating mechanism will be described with reference to FIGS. 9 to 17, various members related to driving the magnetic tape mounted on the slide chassis are omitted.

As shown in FIG. 9, the magnetic tape 1 is housed in a box-shaped cassette case 2 wound around a supply reel 3 and a take-up reel 4. The magnetic tape 1 is exposed by opening the front lid 5 upward so that the magnetic tape 1 can be loaded. As shown in FIGS. 9 to 12, the cassette holder 11 has a box shape with front and rear openings, and the cassette case 2 can be inserted from the front (left in FIG. 11) opening and the rear (FIG. 11). A stopper 12 for regulating the position of the inserted cassette case 2 is formed on the right side of FIG. Support portions 13 and 14 that support the cassette case 2 are formed on the lower portions of both sides of the cassette holder 11. On the other hand, the slide chassis 15 has a box shape with an open top, and the cassette holder 11 is provided on the left and right sides of the lifting mechanism 1.
It is supported by 6 and 17 so that it can be raised and lowered.

As shown in detail in FIG. 11, one lifting mechanism 16 comprises a pair of arms 19 and 20 whose middle portions are connected to each other by a connecting shaft 18 in an X shape.
The front end portion of 0 is the cassette holder 1 by the pivot shafts 21 and 22.
1 and the slide chassis 15, and the rear ends thereof are connected to the slide chassis 15 and the cassette holder 11 by the long holes 23 and 24 and the support shafts 25 and 26. A spring 27 is provided between the pair of arms 19 and 20.
Is stretched and urges the arms 19 and 20 in a standing direction.

As shown in detail in FIG. 12, the other lifting mechanism 17 comprises a pair of arms 29 and 30 having an intermediate portion connected in an X shape by a connecting shaft 28.
The front end of 0 is the cassette holder 1 by the pivots 31 and 32.
1 and the slide chassis 15, and the rear ends thereof are connected to the slide chassis 15 and the cassette holder 11 by the long holes 33 and 34 and the support shafts 35 and 36. A spring 37 is provided between the pair of arms 29 and 30.
Is stretched and urges the arms 29 and 30 in a standing direction.

Therefore, as shown in FIGS. 11 to 14, the cassette holder 11 has arms 19 and 2 of the lifting mechanism 16.
By raising and lowering the 0 and the arms 29 and 30 of the elevating mechanism 17, it is possible to ascend and descend while maintaining a substantially horizontal state.

The left and right lifting mechanisms 16 and 17 are operated at substantially the same speed on the cassette holder 11, that is, the lifting mechanisms 16 and
A synchronization mechanism for synchronizing 17 is provided. As shown in FIGS. 9, 11 and 12, racks 38 and 39 are formed along the upper side of the rear ends of the arms 20 and 30 of the lifting mechanisms 16 and 17, respectively. Pinions 40 and 41 that mesh with the racks 38 and 39 are rotatably attached to the side portions thereof, and the pinions 40 and 41 are connected by a connecting rod 42 so as to rotate integrally.

Therefore, when the cassette holder 11 is horizontally moved up and down by the elevating mechanisms 16 and 17, when the arms 20 and 30 are rotated, the pinions 40 and 41 are moved through the racks 38 and 39.
Are rotated respectively, but this pinion 40, 41
Are connected by a connecting rod 42, so that they rotate in synchronization with each other and the left and right elevating mechanisms 16 and 17 operate at substantially the same speed, and the cassette holder 11 is twisted or slanted when it is moved up and down. Never.
Then, in the lifting mechanisms 16 and 17, the arms 20 and 3
The rear end side of 0, that is, the side on which the racks 38 and 39 are formed is connected to the cassette holder 11 by the long holes 24 and 34 and the support shafts 26 and 36.
39 is a pinion 40 while sliding along with rotation.
41 is rotated at an increased speed, and the lifting mechanism 16, 17
The left and right of will be synchronized.

As described above, the left and right lifting mechanism 1
6, 17, each arm 19, 20 and arm 2
Springs 27 and 37 are stretched on 9 and 30,
The rise of the cassette holder 11 is caused by the springs 27, 3
The biasing force of 7 causes impact force and vibration of the cassette holder 11 due to the biasing force. Therefore, the cassette holder 11 is attached to the lifting mechanisms 16 and 17.
A damper mechanism 43 is provided for reducing shocks and vibrations during ascent and descent to operate gently.

That is, as shown in FIG. 12, in the slide chassis 15, a slide member 45 having a rack 44 formed on the upper side behind the side of the elevating mechanism 17 side is movable back and forth (left and right in FIG. 12). It is supported and one end is connected to the rear end of the arm 29. A pinion 46 that meshes with the rack 44 is rotatably attached to a side portion of the slide chassis 15, and an oil damper 47 is attached to the pinion 46.

Therefore, when the cassette holder 11 is raised by the elevating mechanism 17, the arms 29 and 30 are rotated in the upright direction by the urging force of the spring 37. At this time,
The rear end portion of the arm 29 moves forward together with the slide member 45 and rotates the pinion 46 via the rack 44 of the slide member 45. However, the action of the oil damper 47 slows the rotation of the pinion 46, and the cassette holder 11 It is possible to reduce shocks and vibrations when moving up and down and to operate gently.

Further, one lifting mechanism 17 has each arm 2
A lock mechanism 48 for holding the cassette holders 9 and 30 in a tilted state, that is, the cassette holder 11 in a lowered state is provided. As shown in FIG. 12, in the slide chassis 15, a hook 50 is rotatably attached to a side portion on the side of the elevating mechanism 17 by a shaft 49, and counterclockwise by a spring 51 stretched between the hook 50 and the slide chassis 15. Biased in the direction. Also, the shaft 52 is adjacent to the hook 50.
The restriction plate 53 is rotatably attached by the spring 54 and is urged in the counterclockwise direction by the spring 54, and the tip end thereof abuts the hook 50, so that the hook 50 is rotated against the urging force of the spring 51. It is moved and held at the release position (the position shown in FIG. 12). On the other hand, the arm 30 is integrally formed with a downward extending portion, and the locking pin 55 is fixed to the extending portion. Also, the hook 50
A projecting portion 56 is integrally formed on the lower part of the base chassis 71, and a release lever 105 is formed on a base chassis 71 (described later) that slidably supports the slide chassis 15.

Therefore, the cassette holder 1 shown in FIG.
When 1 is lowered from the raised position (the arms 29 and 30 are in the standing position), the arms 29 and 30 are tilted and the locking pin 55 is lowered. Then, the locking pin 55 is attached to the regulation plate 5.
When the hook 50 is pressed against the urging force of the spring 54 against the urging force of the spring 54, the hook 50 held in the release position by the regulating plate 53 is rotated counterclockwise by the urging force of the spring 51. Therefore, as shown in FIG. 14, the hook 50 is engaged with the locking pin 55 to prevent the arm 30 from standing up, and the cassette holder 11 is moved to the lowered position (arm 29,
30 is restrained in the tilted position). On the other hand, when the protruding portion 56 of the hook 50 contacts the release lever 105 of the base chassis 71, the hook 50 rotates counterclockwise against the biasing force of the spring 51 and engages with the locking pin 55. Is canceled. Then, the arms 29 and 30 stand up by the urging force of the spring 37, and the cassette holder 11
Rises.

In FIGS. 11 and 12, 57,
Reference numeral 58 is each arm arm 19 and 20 of the lifting mechanism 16 and 17.
And 29, 30, the tilted state, that is, the cassette holder 1
1 is a detection switch for detecting the descending state of 1.

As shown in FIGS. 10 and 15, the tape protector 6 is attached to the cassette holder 11 of this embodiment.
1 is provided. When the cassette holder 11 (cassette case 2) descends, the lid 5 of the cassette case 2 opens along with this movement, but at this time, the magnetic tape 1 may adhere to the back side of the lid 5 due to static electricity. The magnetic tape 1 rides on the rotary head drum and is taken to the opposite side, so that it cannot be properly loaded. The tape protector 61 is the magnetic tape 1.
It is intended to prevent the vehicle from riding on the rotary head drum.

That is, a rotating member 63 is attached to the cassette holder 11 by a pivot 62 at the rear of the side of the elevating mechanism 17 side, and two projecting pieces 64, 65 are provided on the outer peripheral portion of the rotating member 63. The rear end portion of the arm 29 of the elevating mechanism 17 can come into contact with the one projecting piece 64. An L-shaped actuating member 66 is rotatably supported by a shaft 67 adjacent to the turning member 63, and one end of the actuating member 66 extending downward contacts one projection 65 of the turning member 63. A long hole 68 is formed at the other end that can be contacted and extends horizontally. Further, at the rear of the cassette holder 11, one end of a tape protector 61 is rotatably attached by a pivot shaft 69 at a position displaced from the center thereof by a predetermined amount toward the elevating mechanism 17 side (right side in FIG. 15). A connecting pin 70 is fixed at a position closer to the other end side of the pivot 69 of 61.
0 is engaged with the long hole 68 of the actuating member 66.

Therefore, when the cassette holder 11 holding the cassette case 2 is in the raised position, as shown in FIGS. 15 and 16, the lid 5 of the cassette case 2 is closed, while the tape protector 61 is in a predetermined position. The tape protector 61 faces downward at an angle θ, and the tip end portion of the tape protector 61 is located at the outer periphery of the rotary head drum 112 mounted on the base chassis 71 and substantially at the center in the radial direction.

When the cassette holder 11 is lowered from this state, as shown in FIGS. 15 and 17, the lid 5 of the cassette case 2 is opened by the release mechanism (not shown), and the magnetic tape 1 is exposed. On the other hand, the arm 2 of the lifting mechanism 17
9 and 30 are tilted, and the rear end of the arm 29 contacts the projecting piece 64 of the rotating member 63 and gradually rotates it in the counterclockwise direction in FIG. Then, the rotating member 6
The protruding piece 65 of No. 3 abuts on one end of the operating member 66 to operate (raise) the other end, and the tape protector 61 is rotated upward as the cassette holder 11 descends. The ascending operation of the tape protector 61 is performed later than the opening operation of the lid 5 of the cassette case 2, and the tape protector 61 has the magnetic tape 1 exposed from the cassette case 2 on the outer peripheral surface of the rotary head drum 112. The climb ends just before facing.

Next, the drive mechanism of the slide chassis, the loading mechanism, the magnetic tape running mechanism and the like will be described with reference to FIGS. 1 to 6, various members related to the cassette holder mounted on the slide chassis are omitted.

As shown in FIGS. 1 and 4, the base chassis 71 has a rectangular plate shape and is fixed in an unillustrated 8 mm video main body, and support pins 72, 73, 7 are provided in four directions.
4,75 are erected. On the other hand, slide chassis 1
5, slide holes 76, 77, 78, 79 are formed on each side along the front-rear direction (vertical direction in FIG. 4). Then, the support pins 72, 7 of the base chassis 71
By engaging the slide holes 76, 77, 78, 79 of the slide chassis 15 with the holes 3, 74, 75, the slide chassis 15 can be moved in the front-rear direction with respect to the base chassis 71. .

In this case, the support pin 73 of the base chassis 71 is the first reference shaft and the support pin 72 is the second reference shaft. Therefore, in the slide holes 76 and 77 with which the support pins 72 and 73 engage, at the unloading position shown in FIGS. 1 and 4, the support pin 72 which is the second reference shaft.
Performs the positioning by contacting the end of the slide hole 76, and the support pin 73 as the first reference shaft does not contact the end of the slide hole 77. On the other hand, at the loading position shown in FIGS. 2 and 5, the support pin 73, which is the first reference shaft, contacts the end of the slide hole 77 for positioning, and the support pin 72, which is the second reference shaft, slides. It does not abut the end of the hole 76. In this way, the slide chassis 71 has slide holes 76, which engage with the support pins 72, 73,
Positioning in the moving direction is performed by 77. Also,
The support pin 73, which is the first reference shaft, and the support pin 72, which is the second reference shaft, are fitted with each other in the width direction of the slide holes 77, 76 with almost no gap therebetween, and the slide chassis 71 is also provided with the support pin 72, Slide holes 76, 7 engaging with 73
Positioning in the width direction is performed by 7.

A drive mechanism for the slide chassis 15 is mounted on the base chassis 71. That is, as shown in FIG. 4, a drive motor 81 having a drive gear 80 is mounted on the rear side of the base chassis 71, and the drive gear 80 meshes with the adjacent first connecting gear 82. The second connection gear 83 coaxially integrated with the first connection gear 82 meshes with the adjacent third connection gear 84, and the fourth connection gear 85 coaxially integrated with the third connection gear 84 is adjacent the fifth connection gear 86. The fifth connecting gear 86 meshes with the sixth connecting gear 87, and the sixth connecting gear 87 meshes with the cam gear 88. A first cam groove 89 is formed on the upper surface of the cam gear 88, while a second cam groove 90 is formed on the lower surface.

The cam gear 8 is attached to the base chassis 71.
8, a drive arm 91 is disposed at a position adjacent to 8, a base end portion of the drive arm 91 is rotatably attached by a pivot shaft (support pin) 73, and a connecting shaft 92 is fixedly attached to a tip end portion thereof. on the other hand,
A support bracket 94 having a connection groove 93 is attached to the slide chassis 15, and the connection shaft 92 of the drive arm 91 is engaged with the connection groove 93. And
A cam shaft 95 is fixed to an intermediate portion of the drive arm 91, and the cam shaft 95 has a first cam groove 89 of a cam gear 88.
Is engaged with.

In this case, the pivot 73 of the drive arm 91 pivotally attached to the base chassis 71 has the slide chassis 1
5 into the slide hole 73 of the slide chassis 1
Since the support pin 73 is used as the first reference axis for positioning in the moving direction of 5, the relative position accuracy between the drive arm 91 and the slide chassis 15 is good.

Therefore, the driving force of the driving motor 81 and the first connecting gear 8 is driven by the driving of the driving motor 81.
2, the second connecting gear 83, the third connecting gear 84, the fourth connecting gear 85, the fifth connecting gear 86, the sixth connecting gear 87, and the cam gear 88 are transmitted, and the cam gear 88 can be rotated. When the cam gear 88 rotates, the first
The cam groove 89 of the drive arm 91 via the cam shaft 93.
Is rotated about the pivot 73, and the slide chassis 15 can be moved along the base chassis 71 via the connecting shaft 92 and the connecting groove 95 (support bracket 94).

Further, the cam gear 8 is attached to the base chassis 71.
8, one end of a connecting link 96 is rotatably attached by a pivot 97 at a position opposite to the drive arm 91. The connecting link 96 has an L shape, and a cam shaft 98 is fixedly connected to the other end of the connecting link 96.
Engages with the second cam groove 90 of the cam gear 88. One end of the connecting lever 99 is connected to the intermediate portion of the connecting link 96 by the connecting pin 100, and the connecting lever 99
The other end of is connected to the operating lever 102 by a connecting pin 101. This actuating lever 102 has a pivot 10 at one end.
It is rotatably attached by 3 and will be described later.
The operation controls the pinch roller 159 (pinch arm 161) and the ratchet brake lever 184.

The cam gear 88 includes the lock control gear 1
04 is meshed, and the lock control gear 104 is cam-engaged with the release lever 105. Therefore, the release lever 105 can be operated to the release position and the non-release position according to the rotation angle of the lock control gear 104, and the protrusion 56 of the hook 50 of the lock mechanism 48 in the cassette holder 11 described above is brought into contact or non-contact. , Hook 5
The disengagement of 0 can be controlled.

Now, the loading mechanism of the magnetic tape 1 will be described. As shown in FIGS. 1, 4, and 7, the intermediate gears 107 and 108 are sequentially meshed with the cam gear 88, and further, the first drive gear 109 and the second drive gear 110.
Are in mesh. On the other hand, on the base chassis 71, a rotary head drum 112 is attached at a substantially central portion thereof via a drum base 111. A ring holder 113 is mounted on the base chassis 71 so as to be in close contact with the drum base 111, and the lower surface of the ring holder 113 has two first ring gears 114 and a second ring gear 114.
The ring gear 115 is rotatably supported in a vertically overlapping state, and the first ring gear 114 includes the first drive gear 1
09, but the second drive gear 110 in the second ring gear 115.
Are engaged with each other. Although not shown, the cam gear 88 and the intermediate gear 107 are partially toothless gears,
The rotation of the cam gear 88, the transmission gear group on the drive source side, and the lock control gear 104 is permitted before the start of loading the first and second ring gears 114 and 115 and after completion thereof.

Therefore, when the drive motor 81 is driven, the driving force is applied to the drive gear 80 and the connecting gears 82,
83, 84, 85, 86, 87, the cam gear 88, the first drive gear 109, and the second drive gear 110, and the first drive gear 109 and the second drive gear 110 rotate in different directions. Then, this first drive gear 109
The first ring gear 114 and the second ring gear 115, which mesh with the second drive gear 110, can rotate in mutually different directions.

Drum base 111 and ring holder 11
3, loading guide grooves 116 and 117 are formed at respective lateral positions (left and right in FIG. 7) around the rotary head drum 112.
One loading guide groove 116 is bifurcated at one end, and the first guide base 118 has a pair of guide pins 11.
It is movably mounted via 9, 120, and a guide roller 121 and guide posts 122, 123 are erected on the first guide base 118. Then, the first guide base 118 is moved to the first position by the connecting lever 124.
It is connected to the ring gear 114. A guide portion 125 is formed along the loading guide groove 116 on the drum base 111 and the ring holder 113, and a guide pin 126 guided by the guide portion 125 is fixed to the first guide base 118.

Further, the other loading guide groove 117
The second guide base 127 has a pair of guide pins 12.
The second guide base 127 is provided with a guide roller 130 and a guide post 131 in an upright position. And the second
The guide base 127 is connected to the second ring gear 115 by a connecting lever 132. An impedance roller 133 is mounted on the ring holder 113 adjacent to the loading guide groove 117.

Therefore, when the first ring gear 114 and the second ring gear 115 rotate in opposite directions, respectively,
The guide base 118 can move along the loading guide groove 116 by transmitting the driving force through the connecting lever 124. At this time, the guide pin 126
Are guided by the guide portion 125, the guide pins 119, 120 are provided at one end of the loading guide groove 116.
Are distributed to each of the two forked grooves. Also, the second
The guide base 127 can move along the loading guide groove 117 by transmitting the driving force via the connecting lever 132.

Next, the magnetic tape running mechanism will be described. As shown in FIG. 4, the capstan (shaft) 134 and the capstan gear 1 are provided on the rear side of the base chassis 71.
A capstan motor 136 having 35 is attached, and the capstan gear 135 is meshed with an adjacent gear pulley 137. On the other hand, slide chassis 15
A turntable 138 on the supply reel 3 side and a turntable 139 on the take-up reel 4 side are rotatably mounted at predetermined positions. The turntable 138 on the supply reel 3 side and the turntable 13 on the take-up reel 4 side
Gear portions 140 and 141 are formed on the outer peripheral portion of the gear 9, respectively. A gear pulley 142 is attached to the base chassis 71 between the turntables 138 and 139, a belt 143 is wound around the gear pulley 137, and a rotation shaft 144 of the gear pulley 142 is attached.
Penetrates the long hole 145 of the slide chassis 15.
Further, a bracket 146 is pivotally mounted on the rotary shaft 144 above the slide chassis 15, and an idle gear 147 that meshes with the gear pulley 142 is mounted on the bracket 146. A clutch member (not shown) that generates rotational friction is provided between the bracket 146 and the idle gear 147.

Therefore, when the capstan motor 136 is driven, the capstan gear 135 rotates, and the rotational force is the gear pulley 137, the belt 143, and the gear pulley 14.
2, transmitted to the idle gear 147. At this time, if the transmitted rotational force is the rotational force in the clockwise direction of the gear pulley 142, the idle gear 147 (bracket 146)
In FIG. 1, the gear portion 14 of the turntable 139 on the take-up reel side is moved to the right around the rotary shaft 144.
It is possible to rotate the turntable 139 in the clockwise direction (the feeding direction of the magnetic tape 1) via the idle gear 147 while meshing with 1. If the transmitted rotational force is the rotational force in the counterclockwise direction of the gear pulley 142, the idle gear 147 (bracket 146) is moved leftward around the rotation shaft 144 in FIG. Gear portion 140 of table 138
It is possible to rotate the turntable 138 in the counterclockwise direction (rewinding direction of the magnetic tape 1) via the idle gear 147 while engaging with. The clutch member described above generates the moving force of the idle gear 147.

As shown in FIG. 1, the slide chassis 15
A guide roller 148 for guiding the magnetic tape 1 at the time of loading and a guide post 149 are movably provided on one side portion (the left portion in FIG. 1). That is, the middle portion of the two links 150, 151 is rotatably attached to the slide chassis 15 by being pivotally supported by the pivots 152, 153, and one end of each link 150, 151 has an engaging pin 154. , 155 penetrate the guide hole 156 to form the guide groove 15 formed in the base chassis 71.
7, 158, and a guide roller 148 and a guide post 149 are attached to the other ends, respectively.

Therefore, when the slide chassis 15 moves backward (upward in FIG. 1), the engaging pins 154, 15
The movement of 5 is restricted by the guide grooves 157 and 158, and the links 150 and 151 respectively rotate counterclockwise. When the links 150 and 151 rotate by a predetermined amount, the engagement pins 154 and 155 move the guide grooves 157 and
By moving along 158, each link 150,15
The guide roller 148 and the guide post 149 provided at the other end of the No. 1 can move to a predetermined position via a predetermined locus.

Further, as shown in FIG. 1, the magnetic tape 1 is guided to the other side portion (right side in FIG. 1) of the slide chassis 15 at the time of loading, and at the time of traveling of the magnetic tape 1, the magnetic tape 1 and the capstan 134. A pinch roller 159 for guiding the magnetic tape 1 and a guide roller 160 are movably provided. That is, the slide chassis 1
5, a pinch arm 161 having a pinch roller 159 attached to one end is rotatably attached by a pivot 162, and a support arm 165 integrally attached with first and second guide pins 163, 164 is also attached by a pivot 162. It is rotatably attached. And each arm 1
A spring 166 is stretched between 61 and 165, and biases the pinch arm 161 in the clockwise direction in FIG. 1 and the support arm 165 in the counterclockwise direction. Is held at the position shown in FIG. 1 by a stopper (not shown).

Further, the first and second guide pins 163 and 164 of the support arm 165 are the slide chassis 1 respectively.
5. First and second guide grooves 16 formed in 5 in an arc shape
7, 168, and a spring 169 is stretched between the support arm 165 and the slide chassis 15 to urge the support arm 165 counterclockwise in FIG.

On the other hand, the base chassis 71 is formed with a restricting portion 170 for restricting the movement of the second guide pin 164. Further, as described above, the operating lever 102 is rotatably attached to the base chassis 71 by the pivot 103, and the operating lever 102 has the engaging groove 171 with which the first guide groove 167 is engaged. Has been formed.

Further, a guide arm 172 is provided on the slide chassis 15 adjacent to the pinch arm 161, and a guide shaft 173 is provided on the pivot shaft 173.
Rotatably mounted by the spring 17
4 is urged in the counterclockwise direction in FIG.

Therefore, when the slide chassis 15 moves rearward (upward in FIG. 1), the movement of the second guide pin 164 of the supporting arm 165 is restricted by the restricting portion 170, and the supporting arm 165 and the pinch arm 161 rotate clockwise. While rotating in the direction, the first and second guide pins 163 and 164 move along the guide grooves 167 and 168, respectively. Then, when the support arm 165 (pinch arm 161) is rotated by a predetermined amount, the second guide pin 164.
Does not rotate due to removal of the movement restriction from the restriction portion 170, and the support arm 165 (pinch arm 161) moves with the slide chassis 15 at the same rotation angle and the first guide pin 163 moves the operating lever 102. Engaging groove 17
Fit in 1. At this time, as shown in FIG. 4, the second cam groove 90 of the cam gear 88 rotates the actuating lever 102 through the connecting link 96 and the connecting lever 99 in the counterclockwise direction in FIG. The support arm 165 and the pinch arm 161 are rotated clockwise through the groove 171 and the first guide pin 163. In this way, the pinch roller 159 can move to a position where it abuts on the capstan 134 via a predetermined locus.

Further, when the pinch roller 159 moves, the guide arm 172 can also rotate clockwise.

Here, the take-up reel 4 side and the supply reel 3
Various brake mechanisms provided on the side will be described.
As shown in FIG. 1, a ratchet brake 181 for restricting rotation of the take-up reel 4 in the pull-out direction (counterclockwise direction in FIG. 1) of the magnetic tape 1 at the time of loading is provided on the take-up reel 4 side. . That is, a ratchet 182 is formed on the outer periphery of the turntable 139 on the take-up reel side, while a ratchet brake lever 184 having a locking claw 183 for locking the ratchet 182 is rotated by the pivot 185 on the slide chassis 15. It is movably attached and is provided with a rotational friction by an urging member (not shown).

The engagement pin 187 is fixed to the ratchet brake lever 184, while the base chassis 7
1, an operation lever 188 is rotatably supported by a pivot (support pin) 75 at a position adjacent to the ratchet brake lever 184, and an engagement piece 189 engageable with an engagement pin 187 is attached to the operation lever 188. Are integrally formed. The operation pin 188 is attached to the operation lever 188.
While 0 is fixed, the operation lever 192 pivotally attached to the base chassis 71 is formed with an operation groove 191 into which the operation pin 190 is inserted. Further, the operating lever 102 is integrally formed with an engaging piece 192 that can be directly engaged with the engaging pin 187 of the ratchet brake lever 184.

Therefore, when the magnetic tape 1 is loaded, the ratchet brake lever 184 causes the locking claw 183 to move the ratchet 182 of the turntable 139 on the take-up reel side by the previous loading and unloading operations.
The magnetic tape 1 is held in a state of being locked to the take-up reel 4 and the magnetic tape 1 is pulled out in the pull-out direction (see FIG. 1).
In the counterclockwise direction) is prevented. At this time, when the actuating lever 102 is rotated counterclockwise about the pivot 103, the operating lever 188 rotates clockwise in FIG. 1 via the operating groove 191 and the operating pin 190. Then, the engagement piece 189 is engaged with the engagement pin 1.
By pressing 87 to rotate the ratchet brake lever 184 counterclockwise in FIG.
The ratchet 182 is released from the lock, the restraint of the turntable 139 is released, and the take-up reel 4 is rotatable in the drawing direction of the magnetic tape 1.

After the loading is completed, when the operating lever 102 is rotated counterclockwise about the pivot 103, the engaging piece 192 is engaged with the engaging pin 1 in the same manner as described above.
By pressing 87 to rotate the ratchet brake lever 184, the restraint of the turntable 139 is released and the take-up reel 4 becomes rotatable.

On the other hand, as shown in FIG. 1, on the side of the supply reel 3, a soft brake 193 for restricting the rotation of the magnetic tape 1 in the magnetic tape supply direction due to the inertial force of the magnetic tape supply reel 3 at the time of loading, and the completion of loading. At the same time, a ratchet brake 194 for restricting rotation in the magnetic tape supply direction is also provided. That is, the band brake 195 is wound around the outer periphery of the turntable 138 on the supply reel side.
One end of the slide chassis 15 is supported by the support member 196.
The other end is connected to the link 150. The soft brake lever 197 is rotatably attached to the slide chassis 15 by a pivot 198, and a pressure contact member 199 that is in pressure contact with the outer peripheral portion of the turntable 138 is attached to the tip end portion thereof.

On the other hand, the ratchet brake lever 200 is also rotatably attached to the slide chassis 15 by a pivot shaft 198, and an engaging claw 201 for engaging with the gear portion 140 of the turntable 138 is integrally formed at the tip end portion thereof. ing. And the soft brake lever 19
7, a spring 202 is stretched between the ratchet brake lever 200 and the soft brake lever 197 in a clockwise direction in FIG. 1, that is, in a direction in which the press contact member 199 presses the outer peripheral portion of the turntable 138. The ratchet brake lever 200 moves in the counterclockwise direction, that is, the locking claw 201 moves to the gear portion 14 of the turntable 138.
It is urged in the direction of locking 0.

The soft brake lever 197 and the ratchet brake lever 200 have cam pins 2 respectively.
03 and 204 are fixed. On the other hand, the drive arm 91
A cam surface 205 as a control unit for controlling the operation of each lever 197, 200 is formed on the cam gear 205, and a cam groove 206 for controlling the operation of the lever 200 is formed on the cam gear 88. In this case, as described above, the drive arm 91 shares the pivot shaft (73) with the support pin 73 as the first reference shaft that fits into the slide hole 73 of the slide chassis 15 and positions in the moving direction. Therefore, the relative positional accuracy between the two is improved, and the operation timings of the soft brake lever 197 and the ratchet brake lever 200 can be made highly accurate.

Therefore, when the magnetic tape 1 is loaded, the soft brake lever 197 is urged clockwise by the urging force of the spring 202, so that the press contact member 199 presses the turntable 138 on the supply reel side, and the magnetic tape is pressed. Rotation in the magnetic tape supply direction (clockwise direction in FIG. 1) by the inertial force of the supply reel 3 is prevented. Further, the ratchet brake lever 200 is held in that position by the cam surface 205 of the drive arm 91 contacting the cam pin 204, and the locking claw 201 is not locked by the gear portion 140 of the turntable 138 on the supply reel side.
The rotation of the supply reel 4 at the time of loading is not blocked.

When the slide chassis 15 is moved rearward (upward in FIG. 1) and loading is performed from this state, the drive arm 91 rotates counterclockwise in FIG. 1, and the cam surface 205 of the drive arm 91 causes the cam pin 203 to move. Through the soft brake lever 197 to the spring 202
Rotate counterclockwise against the urging force of. Then, the pressure contact of the turntable 138 by the pressure contact member 199 is released, and the rotation restriction of the supply reel 3 is released.
On the other hand, with this operation, holding of the cam pin 204 by the cam surface 205 of the drive arm 91 is released, and the ratchet brake lever 184 is locked by the biasing force of the spring 202 by the locking claw 201 to the gear portion 140 of the turntable 139. When the loading is completed, the supply reel 3 is prevented from rotating in the magnetic tape supply direction. Further, after the loading is completed, when the cam gear 88 is further rotated, the ratchet brake lever 184 is rotated by the cam groove 206 via the cam pin 204, whereby the locking claw 201 is formed.
The locking of the gear portion 140 by the
The rotation restriction of is released.

The operation flow of the above-mentioned storage of the cassette 2 in the 8 mm video, loading of the magnetic tape 1 and running drive will be described below.

When the cassette case 2 is mounted in the 8 mm video main body, as shown in FIG. 9, the cassette case 2 is inserted from the front into the cassette holder 11 in the raised position. When the cassette holder 11 is pushed down from the eject (up) position shown in FIGS. 11 and 12, the arms 19, 20 and 29, 30 of the elevating mechanisms 16, 17 are tilted to accommodate the cassette case 2. The cassette holder 11 moves to the lowered position. At this time,
The cassette holder 11 (cassette case 2) can be lowered while maintaining a horizontal state, and the left and right lifting mechanisms 16 and 1
The movement of the arms 20 and 30 in FIG.
By interlocking with each other by the connecting rod 42 via the pinions 40, 41, the left and right lifting mechanisms 16, 17
Will operate synchronously, and the cassette holder 11
It is prevented from twisting or tilting when descending.

As shown in FIGS. 13 and 15, when the cassette holder 11 descends, the cassette holder 1
1 is in the lowered position and is restrained by the lock mechanism 48. That is, when the arms 29 and 30 of the lifting mechanism 17 are tilted, the locking pin 55 is also lowered, and the hook 50 is attached to the locking pin 55.
Engage. Therefore, the arm 30 is prevented from standing up and the cassette holder 11 is restrained in the lowered position. When the detection switch 57 or 58 detects the movement of the cassette holder 11 to the lowered position, the detection switch 57 or 58 gives the information to a microcomputer (not shown) that controls the drive motor and the like, and the microcomputer drives the motor drive circuit. The drive motor 81 is driven via the, and the slide base 15 on which the cassette holder 11 is supported starts to move.

When the cassette holder 11 is in the raised position, as shown in FIGS. 15 and 16, the lid 5 of the cassette case 2 is closed, and the tip of the tape protector 61 is outside the rotary head drum 112. It is located at the periphery and almost at the center in the radial direction. Then, when the cassette holder 11 descends, the lid 5 of the cassette case 2 is opened to open the magnetic tape 1 as shown in FIGS.
Is exposed, while the tape protector 61 is rotated upward as the cassette holder 11 is lowered. At this time, the ascending operation of the tape protector 61 is performed after the opening operation of the lid 5 of the cassette case 2, and the magnetic tape 1 exposed from the cassette case 2 of the cassette holder 11 facing the outer peripheral surface of the rotary head drum 112. In the lowered position, the tape protector 61 rises to a horizontal position.

Therefore, when the cassette holder 11 (cassette case 2) descends, even if the magnetic tape 1 adheres to the back side of the lid 5 due to static electricity accompanying the opening of the lid 5 of the cassette case 2, the magnetic tape 1 1 and rotating drum head 11
Since the tape protector 61 is located between the magnetic tape 1 and the magnetic tape 2, the magnetic tape 1 is prevented from riding on the rotary head drum 112.

When the cassette holder 11 is completely moved to the lowered position and is locked in the lowered position by the lock mechanism 48, the drive motor 81 is driven and the cassette holder 11 is moved.
The slide base 15 supported by is slid. That is, as shown in FIGS. 1 and 4, when the drive motor 81 is driven, the driving force is generated by the drive gear 80 and the connecting gears 8.
Cam gear 8 through 2,83,84,85,86,87
8 and the cam gear 88 rotates. Then,
With the first cam groove 89 of the cam gear 88, the drive arm 91 is rotated counterclockwise in the figure via the cam shaft 95, and as shown in FIGS. Base chassis 71
The support pin 73, which is the first reference shaft, comes into contact with the end of the slide hole 77 and stops positioning at a predetermined loading position.

The magnetic tape 1 is loaded as the slide chassis 15 is slid by the drive motor 81. That is, the ejecting (lowering) position of the slide chassis 15 shown in FIGS. 1 and 4 is the unloading state of the magnetic tape 1. From this state, the slide chassis 15 is slid and the magnetic tape 1 is pulled out for loading. Then, the loading state of the magnetic tape 1 shown in FIGS. 2 and 5 is set.

As shown in FIGS. 2 and 5, the drive motor 8
When 1 is driven, as described above, the cam gear 88 rotates, the driving force thereof is transmitted to the first drive gear 109 and the second drive gear 110, and the first ring gear 114 and the second ring gear 115 are in different directions. That is, the first ring gear 114 rotates in the counterclockwise direction and the second ring gear 115 rotates in the clockwise direction in FIG. Then, as shown in FIG. 7, the first guide base 118 moves along the loading guide groove 116, while the second guide base 127 moves along the loading guide groove 117.

At this time, the first guide base 118 slightly rotates at the end of the loading guide groove 116. That is, as shown in FIG.
The guide pins 119 and 120 are the loading guide grooves 1
While being guided by 16, the guide pin 126 moves while being guided by the guide portion 125. Then, when the first guide base 118 moves to the terminal end portion of the loading guide groove 116, the guide pins 126 are constrained by the guide portion 125, so that the guide pins 119, 12 are formed.
0 moves while being divided into two forked portions of the loading guide groove 116.

Therefore, the magnetic tape 1 in the cassette case 2 has the guide roller 121 of the first guide base 118, the guide posts 122 and 123, and the second guide base 127.
Is pulled out by the guide roller 130 and the guide post 131 and slidably contacts the outer peripheral surface of the rotary head drum 112.

The magnetic tape 1 is loaded by the movement of the first and second guide bases 118 and 127, and also loaded by a plurality of guide rollers or guide posts on both sides of the rotary head drum 112. As shown in FIGS. 1 and 2, at one side of the slide chassis 15, the slide chassis 15
Moves backward, pin 1 of each link 150, 151
54 and 155 move by the guide grooves 157 and 158, and the links 150 and 151 rotate, respectively.
Then, the guide roller 148 of each link 150, 151
And the guide post 149 moves to pull out the magnetic tape 1.

Further, when the slide chassis 15 moves rearward on the other side of the slide chassis 15, the second guide pin 164 of the support arm 165 is restricted by the restriction part 170 so that the support arm 165 and the pinch arm 161 rotate. Move. Then, when the support arm 165 rotates by a predetermined amount, the second guide pin 164 disengages from the restricting portion 170, and the first and second guide pins 163 and 164 move along the guide grooves 167 and 168 to move the first guide pin 165. 163
Fits into the engaging groove 171 of the operating lever 102. In this way, the pinch roller 159 moves to pull out the magnetic tape 1. Further, when the pinch roller 159 moves, the guide arm 172 rotates to move the guide roller 160.
Guides the magnetic tape 1.

Various brakes 181, are provided on the supply reel 3 and the take-up reel 4 of the cassette case 2 on which the magnetic tape 1 is wound when the magnetic tape 1 is loaded.
193 and 194 are operating.

When the magnetic tape 1 is loaded, as shown in FIG. 1, the ratchet brake lever 184 on the take-up reel 4 side causes the locking claw 183 to move to the take-up reel side turntable 139 by the previous loading and unloading operations. The ratchet 182 is held in a locked state, and rotation of the magnetic tape 1 in the pull-out direction (counterclockwise direction in FIG. 1) at the time of loading on the take-up reel 4 is prevented. Therefore, the magnetic tape 1 is not pulled out from the take-up reel 4 at the time of loading, and is prevented from being recorded again on the recorded magnetic tape 1 wound on the take-up reel 4.

By the way, when the magnetic tape 1 in the cassette case 2 inserted in the cassette holder 11 is entirely wound around the take-up reel 4 and there is no magnetic tape 1 wound around the supply reel 3, loading is performed. I can't
The magnetic tape 1 is cut. In this case, this is detected by a detector (not shown), and the operating lever 102 is rotated counterclockwise around the pivot 103 from the state shown in FIG. 1 to rotate the operating lever 188 clockwise. Then, the engagement piece 189 is engaged with the engagement pin 187.
By pressing to rotate the ratchet brake lever 184 in the counterclockwise direction, the locking of the ratchet 182 by the locking claw 183 is released, and the turntable 139 is released from the constraint. It can be rotated in the pulling direction.

When loading the magnetic tape 1,
As shown in FIG. 1, the soft brake lever 197 is rotated in the magnetic tape supply direction by the inertial force of the supply reel 3 when the pressing member 199 is pressed against the turntable 138 on the supply reel side by the urging force of the spring 202. Block. Then, when the loading is completed, as shown in FIG. 2, the cam surface 205 of the drive arm 91 rotates the soft brake lever 197 via the cam pin 203, and the pressure contact of the pressure contact member 199 to the turntable 138 is released. The rotation restriction of the supply reel 3 is released.

On the other hand, when loading the magnetic tape 1,
As shown in FIG. 1, the ratchet brake lever 200 is held in that position by the cam surface 205 of the drive arm 91 contacting the cam pin 204, and the locking claw 201 is not locked by the gear portion 140 of the turntable 138. The rotation of the supply reel 3 is not blocked. Then, when the loading is completed, as shown in FIG.
The holding of the cam pin 204 by 05 is released, and the ratchet brake lever 200 is locked by the spring 202 by the locking claw 201 to the gear portion 140 of the turntable 138, so that the supply reel 3 is prevented from rotating in the magnetic tape supply direction. To be done.

As described above, the magnetic tape 1 includes the guide rollers 121, 130, 148, 160, the guide posts 122, 123, 131, 149, and the pinch roller 159.
Thus, it is pulled out from the cassette case 2 and loaded on a predetermined locus. The loading state of the magnetic tape 1 shown in FIGS. 2 and 5 is a stop state in 8 mm video.

When the operator presses the play button in this state, the drive motor 81 is driven again, and as shown in FIGS. 3 and 6, the cam gear 88 rotates and the second cam groove 90 causes the connecting link 96 and The operating lever 102 is rotated counterclockwise in FIG. 5 via the connecting lever 99.
Then, the support arm 165 and the pinch arm 161 are rotated clockwise through the engagement groove 171 of the operating lever 102 and the first guide pin 163. Therefore, the pinch roller 159 comes into contact with the capstan 134 and moves to a position sandwiching the magnetic tape 1 together with the capstan 134, and the drive motor 81 stops.

Further, as described above, the operating lever 102
When is rotated, the engaging piece 192 pushes the engaging pin 187 to rotate the ratchet brake lever 184, whereby the restraint of the turntable 139 is released and the take-up reel 4 becomes rotatable. Further, when the cam gear 88 rotates, the ratchet brake lever 184 is rotated by the cam groove 206 via the cam pin 204, whereby the locking claw 201 is released.
The locking of the gear portion 140 by the
The rotation restriction of is released.

In this way, the supply reel 3 and the take-up reel 4
When the rotation restriction is released, the take-up reel 4 is driven to rotate and the magnetic tape can run. That is, as shown in FIG. 3, when the capstan motor 136 is driven, the capstan gear 135 rotates and its rotational force is transmitted to the gear pulley 142 via the gear pulley 137 and the belt 143. Rotate clockwise. Then, the idle gear 147 rotates counterclockwise in FIG.
46 rotates rightward about the rotary shaft 144, and the idle gear 147 turns the turntable 139 on the take-up reel side.
Mesh with the gear part 141 of the. Therefore, the idle gear 14
The rotational force of No. 7 is transmitted to the turntable 139, and the turntable 139 rotates clockwise. Then, the take-up reel 4 rotates in the same direction and the magnetic tape 1
Runs in the feed direction. Then, recording or reproduction can be performed as the magnetic tape 1 runs.

As shown in FIG. 3, the running path of the magnetic tape 1 is such that the magnetic tape 1 pulled out from the cassette case 2 is guided by the guide roller 148 and the guide post 14.
9, impedance roller 133, guide roller 13
0, the rotary head drum 11 via the guide post 131
2 is slidably contacted with the outer peripheral surface of the guide posts 122, 123,
It passes through the guide roller 121, the capstan 134 (pinch roller 159), and the guide roller 160, and then enters the cassette case 2 again.

When recording or reproduction of the magnetic tape 1 is completed and the operator presses the stop button while the magnetic tape 1 is running, the capstan motor 136 is stopped, the rotation of the take-up reel 4 is stopped and the magnetic tape 1 is driven. The motor 81 rotates in the opposite direction, and the pinch roller 159 moves the capstan 13
4 and the state shown in FIGS. 2 and 5 is obtained. Also,
The ratchet brake 181 restrains the take-up reel 4 to prevent its rotation, and the ratchet brake 194 prevents the take-up reel 4 from rotating.
Restrain the rotation to prevent rotation.

When the operator presses the eject button when the magnetic tape 1 is stopped, the drive motor 81 rotates in the reverse direction to release the loading of the magnetic tape 1 and return it into the cassette case 2, and the slide chassis 15 moves forward. It slides (downward in FIGS. 2 and 5) to the unloading state shown in FIGS. 1 and 4.

When the slide chassis 15 moves to the eject position (unloading state) shown in FIGS. 1 and 4, the base chassis 7 is moved as shown in FIGS. 13 and 14.
The protrusion 56 of the hook 50 contacts the release lever 105 of No. 1 and the hook 50 rotates counterclockwise against the urging force of the spring 51 to release the engagement with the locking pin 55. It Then, the arms 29, 3 of the lifting mechanism 17
0 is erected by the urging force of the spring 37, and the arms 19, 20 of the elevating mechanism 16 are erected by the urging force of the spring 27, and the cassette holder 11 is raised.

When the cassette holder 11 is raised by the elevating mechanisms 16 and 17, the cassette holder 11 is raised by the urging force of the springs 27 and 37, but when the arm 29 is erected, its rear end moves forward together with the slide member 45. Then, by rotating the pinion 46 via the rack 44, the rotation of the pinion 46 is moderated by the action of the oil damper 47, and the cassette holder 1
The shock and vibration at the time of lifting and lowering of No. 1 are alleviated and the operation is gentle.

After the cassette holder 11 is raised, the cassette case 2 can be taken out of the cassette holder 11.

[0092]

As described above in detail with reference to the embodiments, according to the slide mechanism of the magnetic recording / reproducing apparatus of the present invention, in the magnetic recording / reproducing apparatus, the pivot of the base end of the drive arm is set to the base chassis. Since it is also used as a support shaft for movably supporting the standing slide chassis, the relative position accuracy of the drive arm and slide chassis can be maintained with high accuracy, and the positioning of the slide chassis at each movement stop position is accurate. It is possible to reduce the size and weight of the device and to reduce the cost. Also, since the pivot of the release lever of the ratchet brake that regulates the rotation of the take-up reel in the tape unwinding direction is used together with the pivot of the drive arm, it is also used as another support shaft of the base chassis, which further reduces the size and weight of the device and reduces costs. It can be reduced.

[Brief description of drawings]

FIG. 1 is a plan view of a slide chassis showing an eject (cassette attachment / detachment) state in an 8 mm video equipped with a slide mechanism of a magnetic recording / reproducing apparatus according to an embodiment of the present invention.

FIG. 2 is a plan view of a slide chassis showing a loading state.

FIG. 3 is a plan view of a slide chassis showing a tape running state.

FIG. 4 is a plan view of the base chassis showing an eject (cassette attachment / detachment) state in an 8 mm video.

FIG. 5 is a plan view of the base chassis showing a loading state.

FIG. 6 is a plan view of a base chassis showing a tape running state.

FIG. 7 is a plan view showing a loading mechanism.

FIG. 8 is a schematic view showing a loading operation state.

FIG. 9 is a perspective view of a cassette holder.

FIG. 10 is a plan view of the cassette holder.

FIG. 11 is a right side view of the cassette holder.

FIG. 12 is a left side view of the cassette holder.

FIG. 13 is a right side view of the cassette holder showing a cassette stored state.

FIG. 14 is a left side view of the cassette holder showing a cassette stored state.

FIG. 15 is a front view of the cassette holder.

FIG. 16 is an operation explanatory view showing the positional relationship between the cassette case and the rotary head drum.

FIG. 17 is an operation explanatory view showing the positional relationship between the cassette case and the rotary head drum.

[Explanation of symbols]

 1 magnetic tape 2 cassette case 3 supply reel 4 take-up reel 11 cassette holder 15 slide chassis 16,17 lifting mechanism 48 locking mechanism 71 base chassis 72 support pin (second reference axis) 73 support pin (first reference axis) 74, 75 Support Pin 76, 77, 78, 79 Slide Hole 81 Drive Motor 88 Cam Gear 89, 90 Cam Groove 91 Drive Arm 112 Rotating Head Drum

Claims (2)

[Claims] 1. A support shaft is provided upright on both sides of a base chassis mounted in the apparatus, and a long hole is formed in a slide chassis supporting a cassette along a moving direction so that the support shaft has the long length. The slide chassis is slidably supported by the base chassis by being inserted into the hole, the base chassis and the slide chassis are connected by a drive arm, and the drive arm is rotated by a cam gear which is rotatable and driven. As a result, in the magnetic recording / reproducing apparatus in which the slide chassis is movable between the cassette attaching / detaching position and the recording / reproducing position, the base end of the drive arm is rotated by one of the support shafts erected on the base chassis. A slide mechanism for a magnetic recording / reproducing apparatus, which is movably supported. 2. A supporting shaft is provided upright on both sides of a base chassis mounted in the apparatus, and a long hole is formed in a slide chassis supporting a cassette along a moving direction so that the supporting shaft has the long length. The slide chassis is slidably supported by the base chassis by being inserted into the hole, the base chassis and the slide chassis are connected by a drive arm, and the drive arm is rotated by a cam gear which is rotatable and driven. As a result, the slide chassis can be moved between the cassette attachment / detachment position and the recording / reproducing position, and the slide chassis is locked at a predetermined time in the rotating body on the magnetic tape take-up reel side so as to move in the tape take-out direction of the take-up reel. In a magnetic recording / reproducing apparatus provided with a ratchet brake that restricts rotation and a release lever for the ratchet brake, the base end of the drive arm is fixed to the base. A slide mechanism of a magnetic recording / reproducing apparatus, which is rotatably supported by one of the support shafts provided upright on the chassis and the base end portion of the release lever is rotatably supported by the other support shaft. .