Compact rotary magnetic disc device having a magnetic disc holder

A rotary magnetic disc device suitable for use in a magnetic recording/reproducing apparatus in an electronic still camera or the like. In the rotary magnetic disc device, a cover lock mechanism, a regulation plate drive mechanism and a center core push drive mechanism can be operated by use of a movable plate the movement of which can be controlled by a cam and, therefore, an operation to remove the locking of a cover, an operation to retreat a regulation plate and an operation to remove the pushing against a center core can be performed by a single drive source, so that a compact rotary magnetic disc device can be obtained.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a rotary magnetic disc device and, in 
particular, to a rotary magnetic disc device which is suitable for use in 
a magnetic recording/reproducing apparatus in an electronic still camera 
or the like. 
2. Description of the Related Art 
Recently, there has been developed an attractive electronic still camera 
system in which an image pickup device such as a solid image pickup 
element, an image pickup tube or the like is combined with a recording 
device employing as a recording medium thereof an inexpensive magnetic 
disc having a relatively larger storage capacity such that an object can 
be still photographed electronically and recorded into a rotating magnetic 
disc and the reproduction of the recorded image can be performed by means 
of a television system, a printer or the like which is provided separately 
from the electronic still camera system. 
The magnetic disc that is employed in such camera system is usually used in 
the form of a magnetic disc pack. In the magnetic disc pack there is 
rotatably stored a magnetic disc which is capable of magnetic recording of 
still image information or the like, and such magnetic disc pack is used 
after it is mounted to a rotary magnetic disc device which is incorporated 
in an electronic camera. 
When the magnetic disc pack is mounted to the magnetic recording or 
reproducing apparatus in the electronic camera, it is troublesome and 
inconvenient to directly mount or locate a central bore, which is formed 
in a center core disposed in the central portion of the magnetic disc 
within the magnetic disc pack, onto a rotary drive shaft which is 
positioned on the side of the magnetic recording or reproducing apparatus. 
For this reason, such locating operation may result in the inaccurate 
mounting of the magnetic disc pack to the magnetic recording or 
reproducing apparatus. 
In order to eliminate the above-mentioned problem, conventionally, there 
has been proposed a magnetic disc pack loading/unloading device which 
comprises a cover supported to the main body of the magnetic recording or 
reproducing apparatus such that it can be freely opened or closed, and a 
pack holder which can be operated cooperatively with the cover and in 
which the magnetic disc pack can be stored. That is, in the magnetic disc 
pack loading/unloading device, by closing the cover after insertion of the 
magnetic disc pack into the pack holder, a magnetic disc in the magnetic 
disc pack within the pack holder can be mounted to the rotary drive shaft 
of the main body of the magnetic recording or reproducing apparatus. 
By the way, in the above-mentioned magnetic disc pack loading/unloading 
device, there is a necessary center core push member which is used to 
securely mount the center core of the magnetic disc to the rotary drive 
shaft. The center core push member is adapted such that, when closing the 
cover, it pushes against the center core of the magnetic disc from above 
toward the drive shaft and, during the magnetic recording or reproducing 
operation, it gets detached from the center core of the magnetic disc. 
Also, in such magnetic disc pack loading/unloading device, there must be 
provided a regulation plate which is disposed at a position opposing to a 
magnetic head and is used to run the magnetic disc along the magnetic head 
during the magnetic recording or reproducing operation. The regulation 
plate is located at a position opposed to the magnetic head with the 
magnetic disc therebetween during the magnetic recording or reproducing 
operation However, in operations other operations than the magnetic 
recording or reproducing operation, the regulation plate must be separated 
from the magnetic head so as to prevent production of any pressure traces 
on the magnetic disc. 
As mentioned above, in the rotary magnetic disc device in accordance with 
the prior art, there are necessarily a cover lock mechanism, a center core 
push drive mechanism, a regution plate drive mechanism and the like which 
need drive sources, respectively. The provision of the respective drive 
source requires a large space therefor. 
SUMMARY OF THE INVENTION 
The present invention aims at eliminating the drawbacks found in the 
above-mentioned prior art rotary magnetic disc device. 
Accordingly, it is an object of the present invention to provide a compact 
rotary magnetic disc device in which a locked cover can be unlocked, the 
pushing of a center core can be removed and a regulation plate can be 
retreated by a single and common drive source. 
In order to accomplish the above object, according to the present 
invention, there is provided a rotary magnetic disc device which 
comprises: a main body; a cover journaled to said device main body such 
that it can be freely opened or closed; a pack holder operable 
cooperatively with said cover, journaled to said device main body such 
that it can be freely opened or closed, and formed in such a shape as to 
be able to store a magnetic disc pack therein; a first rotary drive source 
disposed in said device main body and adapted such that, while said cover 
is closed, a rotary drive shaft thereof can be fitted into a center core 
provided in a magnetic disc to rotate said magnetic disc; a cover lock 
mechanism which is used to secure said cover while said cover is closed; a 
regulation plate drive mechanism adapted to allow a regulation plate to be 
advanced or retreated with respect to a mgnetic head while said cover is 
closed; a center core push member disposed internally of said cover in a 
freely rotatable manner and adapted such that, while said cover is closed, 
if said push member is inclined in a predetermined amount, it can push 
against said center core by means of the center core push portion thereof; 
a center core push drive mechanism adapted to incline said center core 
push member; a second rotary drive source disposed in said device main 
body; a cam connected with and driven by said second rotary drive source; 
and, a movable plate provided with a follower the movement of which can be 
controlled by said cam and also adapted to operate said cover lock 
mechanism, regulation plate drive mechanism and center core push drive 
mechanism.

DETAILED DESCRIPTION OF THE INVENTION 
Detailed description will hereunder be given of the preferred embodiments 
of a rotary magnetic disc device according to the present invention with 
reference to the accompanying drawings. 
Referring first to FIG. 1, there is illustrated a general structure of an 
electronic still camera to which a rotary magnetic disc device of the 
invention is applied. In this figure, reference numeral 1 designates a 
camera body, 2 a photographing lens mount, 3 a finder, 4 a rotary magnetic 
disc device, 5 a knob for opening a cover of the rotary magnetic disc 
device, and 6 a shutter release button of the electronic still camera. 
Next, the structure of a magnetic disc pack to be mounted onto the rotary 
magnetic disc device 4 will be described in connection with FIGS. 2 and 3. 
In FIG. 2, there is shown a plane view of the magnetic disc pack and, in 
FIG. 3, there is shown a section view of the magnetic disc pack taken 
along a line A--A in FIG. 2. As shown in FIG. 2, the magnetic disc pack 10 
is formed in a substantially square shape and, within the square-shaped 
disc pack 10, there is stored a magnetic disc 12 in a freely rotatable 
manner into which still image information or the like can be recorded. In 
the central part of the magnetic disc 12 there is provided a center core 
14 which serves as a reinforcing member of the magnetic disc 12. The 
center core 14 is exposed externally from a circular opening formed in the 
magnetic disc pack 10. In the magnetic disc pack 10 there is formed a 
window portion 18 in which a magnetic head is to be positioned, and the 
window portion 18 for a magnetic head can be opened or closed by means of 
a slidable shutter 20. That is, before the magnetic disc pack 10 is 
inserted into a pack holder 26, the shutter 20 closes the window portion 
18 to prevent the magnetic disc 12 from being attached by dust. After the 
pack 10 is inserted into the pack holder 26, the shutter 20 moves in a 
downward direction in FIG. 2 to open the magnetic head window portion 18, 
thereby permitting recording into or reproducing from the magnetic disc 
12. 
Referring now to FIGS. 4 to 6, there is shown the internal structure of an 
embodiment of a rotary magnetic disc device according to the invention. In 
this embodiment, the rotary magnetic disc device comprises a main body 24, 
a pack holder 26 and a cover 28. Referring first to the structure of the 
device main body 24, within the device main body 24 there is provided a 
motor 30 for driving a magnetic disc which is provided with a drive shaft 
32. The drive shaft 32 can be inserted into a central bore 15 formed in a 
center core 14 disposed in a magnetic disc pack 10 shown in FIG. 3 so as 
to rotate the magnetic disc 12 at a given number of rotations within the 
magnetic disc pack 10. Also, in FIG. 5, reference numeral 34 designates a 
motor which is used to feed a magnetic head, 36 a lead screw connected via 
gears 34A, 34B to the output shaft of the motor 34, 38 a head carriage 
threadedly engageable with the lead screw 36 and also adapted such that it 
can be guided and moved by a guide shaft 40, and 42 a magnetic head 
provided on the head carriage 38. Accordingly, if the motor 34 is rotated 
at every given number of rotations, then the head carriage 38 can be moved 
at every given pitch in the axial direction of the guide shaft 40 by means 
of rotation of the lead screw 36, so that the magnetic head 42 is moved in 
the radial direction of the magnetic disc 12 so as to be able to record or 
reproduce still image information on the magnetic disc 12, that is, at 
each of tracks provided on the magnetic disc 12. 
Also, on the two ends of the device main body 24, there are provided two 
brackets 44, 44 (in FIG. 4, only one of them is shown), respectively, to 
which brackets 44, 44 the pack holder 26 and the cover 28 are pivotally 
supported via a pin 46. The cover 28 is energized in a direction to open 
with respect to the device main body 24 by a spring which is not shown, 
and also between the cover 28 and the pack holder 26 there is interposed 
another spring which is energizing the pack holder 26 in a direction away 
from the cover. Therefore, as shown in FIG. 4, in a state where the cover 
28 is open, the pack holder 26 stands away from both the device main body 
24 and the cover 28 to open a magnetic disc pack insertion opening 48 
formed in the pack holder 26. 
As shown in FIG. 4, the cover 28 is provided with a regulation plate holder 
50 such that it can be moved a very slight distance in a vertical 
direction. The regulation plate holder 50 is equipped with a regulation 
plate 52, a P.G sensor 54 and the like. The regulation plate holder 50 is 
energized by a plate spring 56 in a downward direction, that is, toward 
the magnetic head. Also, as shown in FIGS. 4 and 5, an end portion 50A 
provided in the front portion of the regulation plate holder 50 is 
projected out from an opening 28A formed in the front edge of the cover 
28. 
Also, the cover 28 is further provided with a center core push member 60 in 
such a manner that it can be moved a very slight distance. The center core 
push member 60, as shown in FIG. 7, is composed of a plate spring 62 and a 
lever 66 connected via a pin 64 to the plate spring 62. The pin 64 is 
staked to the cover in such a manner that it is loosely fitted through the 
plate spring 62 and the lever 66. There is formed a slight clearance 
between the rear surface of the cover 28 and the plate spring 62, lever 
66. In the front end portion of the plate spring 62 there are formed three 
center core push portions 67, 67, 67 and the the plate spring 62 is 
further provided with a substantially dogleg-shaped portion 68 in the rear 
end thereof. Therefore, in a state in which an upwardly pushing force is 
not acted on the lever 66, as shown in FIG. 7, due to the energizing force 
of the dogleg-shaped portion 68 of the spring 62, a force to energize in a 
clockwise direction with the pin 64 being a fulcrum is applied onto the 
lever 66, so that the center core push portions 67 in the front end 
portion of the plate spring 62 are being separated from the center core 14 
of the magnetic disc 12. As shown in FIG. 8, if an external force is 
exerted onto the lever 66 against the dogleg-shaped portion 68 of the 
plate spring 62, then the lever 66 is caused to rotate counterclockwise 
about the pin 64 and the plate spring 62 provided in the lever is also 
rotated similarly, so that, as shown in FIG. 8, the center core push 
portions 67 of the plate spring are brought into contact with the center 
core 14 to push against the center core 14 toward the drive shaft 32. The 
lever 66 also includes an end portion 66A which is projected externally 
out of another opening 28B formed in the cover 28. 
As shown in FIG. 5, in the depth-side end portion of the device main body 
24, there is arranged a second drive source 70 which is provided with an 
output shaft. The output shaft of the second drive source 70 is provided 
with a worm 72 which meshes with a worm gear 74. The worm gear 74 is 
connected with a drive shaft 76 and the drive shaft 76 is in turn 
connected with a gear 78 which is shown in FIG. 9. The gear 78 meshes with 
a gear 80 and a gear 82, coaxial with the gear 80, engages with a cam gear 
84. The cam gear 84 is shaped in the form of a double cam. In one of the 
two surfaces (that is, the front surface) of the cam gear 84 there is 
formed a recessed portion 86. When a switch piece 88 is situated in this 
recessed portion 86, its contact with a switch piece 90 is removed, with 
the result that a switch 92 is turned off. The switch 92 is used to detect 
the rotational reference position of the cam gear 84. 
The other surface (that is, the rear surface) of the cam gear 84 is shown 
in FIGS. 10 through 13. FIGS. 10 through 13 are respective views obtained 
by observing the relevent portion of the present device from behind FIG. 9 
and, therefore, in FIGS. 9 and 10 the same parts are reversed in the right 
and left positions thereof with respect to each other. The cam gear 84 is 
provided with a groove cam 94 and a follower 98 planted on a slide plate 
96 is fitted into the groove cam 94. In the slide plate 96, as shown in 
FIG. 9, there are formed large and small elongated bores 99, 100. Pins 
102, 104 planted from the device main body 24 are positioned in the large 
and small elongated bores 99, 100, respectively, so that the slide plate 
96 can be guided by guide pins 102, 104 to move a given distance in the 
right and left direction in FIG. 9. Therefore, when the cam gear 84 is 
rotated, then the slide plate 96 is moved in the right and left direction 
in FIG. 9. 
As shown in FIG. 10, the device main body 24 is provided with a regulation 
plate drive lever 106. The regulation plate drive lever 106 is rotatably 
supported by a pin 108 and is also energized by a spring 109 in a 
counterclockwise direction in FIG. 10. Also, the regulation plate drive 
lever 106 is provided with a pin 110 which is situated in an opening 112 
(which is shown in FIG. 9) formed in the slide plate 96. Therefore, if the 
slide plate 96 is moved in the left direction in FIG. 9 by means of action 
of the cam gear 84, the pin 110 is pushed by the side edge 114 of the 
opening 112 and is then rotated against the energizing force of the 
spring. As a result of this, the end member 50A of the regulation plate 
holder 50 is pushed up by the lever 106, so that the regulation plate is 
moved into its retreat position from its set position. 
Also, in the device main body 24, there is supported a center core push 
member drive lever 116 in such a manner that it can be freely rotated 
about a pin 118. This drive lever 116 is also rotatively energized in a 
counterclockwise direction in FIG. 10 by a spring 117. 
Further, in the drive lever 116 there is planted a pin 120 which is 
positioned within an opening 122 (which is shown in FIG. 9) formed in the 
slide plate 96. For this reason, if the slide plate 122 is moved in the 
left direction in FIG. 9, then the pin 120 is pushed by the side edge 124 
of the opening 122, so that in FIG. 10 the drive lever 116 is rotated 
clockwise against the energizing force of the spring 117. The center core 
push member drive lever 116 has an upper end portion which, as shown in 
FIG. 10, is in contact with the end portion 66A of the lever 66 of the 
center core push member 60. Therefore, when the center core push member 
drive lever 116 is rotated clockwise about the pin 118 in FIG. 10 due to 
the movement of the slide plate 96, then the contact of the upper end 
portion thereof with the lever end portion is removed so that the lever 66 
is moved downward and the center core push portion 67 is separated from 
the center core 14 of the magnetic disc 12, thereby providing the magnetic 
recording or reproduction enabling state. 
Moreover, in the device main body 24 there is supported a cover lock lever 
126 in such a manner that it can be freely rotated about a pin 128. The 
cover lock lever is also rotatively energized by a spring 130 in a 
counterclockwise direction in FIG. 10. The cover lock lever 126 is 
provided in the upper end portion thereof with a lock piece 126A which is 
formed by folding. The lock piece 126A is initially brought into contact 
with the front edge 29 of the cover 28 when the cover 28 is closed and, 
during such initial contact, the lock lever 126 is rotated slightly in a 
counterclockwise direction. And, when the projection piece 29A of the 
front edge 29 is located below the lock piece 126A, the lock lever 126 is 
rotated clockwise in FIG. 10 due to the energizing force of the spring 130 
so that, as shown in FIG. 10, it is able to lock the front edge 29 of the 
cover 28. In the lock lever 126 there is planted a pin 132 which is 
positioned within a rectangular opening 134 formed in the slide plate 96 
as shown in FIG. 9. Therefore, if the slide plate 96 is moved in the right 
direction in FIG. 9, then the pin 132 is pushed by the side edge 136 of 
the opening 134 and is rotated counterclockwise against the energizing 
force of the spring 130 in FIG. 10 to remove the engagement between the 
lock piece 126A and the projection piece 29A, so that the locking of the 
cover 28 can be unlocked. 
In addition, there is supported a switch operation lever 138 in such a 
manner that it can be freely rotated about 118 and the switch operation 
lever 138 is also rotatively energized counterclockwise in FIG. 10 by a 
spring 140 which is shown in FIG. 9. When the cover 28 is closed to bring 
the lower portion 29B of the front edge 29 into contact with a receive 
portion 142, then the switch operation lever 138 is removed off from a 
contact 146 provided in a switch 144, whereby the switch 144 is operated 
to detect that the cover 28 is closed, which permits preparation for the 
magnetic recording or reproducing state. That is, while the cover 28 is 
open, the switch operation lever 138 turns on the switch 144 as shown in 
FIG. 9, and when the cover 28 is completely closed, the end portion 138A 
of the switch operation lever 138 is disconnected from the contact 146 of 
the switch 144 to turn off the switch 144 as shown in FIG. 10, which is a 
starting point of an operation to provide the next magnetic recording or 
reproducing state. 
Now, we will describe below the operation of the above embodiment of the 
rotary magnetic disc device of the invention that is constructed in the 
above-mentioned manner. At first, in the state shown in FIG. 1 in which 
the present rotary magnetic disc device is open, the magnetic disc pack 10 
is inserted into the pack holder 26. When the magnetic disc pack 10 is 
inserted within the pack holder 26, the magnetic disc pack 10 is guided 
and inserted into the two side end portions of the pack holder 26. After 
the magnetic disc pack 10 has been completely inserted into the pack 
holder 26, if the cover 28 is pushed down toward the device main body 24, 
then the center core 14 is mounted onto the drive shaft 32 and at the same 
time the switch operation lever 138 is rotated by the front edge 29 of the 
cover 28 to operate the switch 144. This state is shown in FIG. 10. The 
cover 28 is secured by the lock piece 126A of the lever 126 and at the 
same time the lever 116 pushes up the end portion 66A of the lever 66 to 
thereby perform the center core push operation. 
Next, the second drive source 70 is operated; that is, the rotational force 
of the second drive source 70 is transmitted through the worm 72, worm 
gear 74 and drive shaft 76 to the gear 78, and the rotational force of the 
gear 78 is then transmitted through the gears 80, 82 to the cam gear 84. 
When the cam gear 84 is thus rotated, then the slide plate 96 is moved in 
the right and left direction in FIG. 9 by the cam groove 94 formed in the 
cam gear 84. 
Specifically, if the slide plate 96 is moved in the left direction in FIG. 
9 by means of the rotational movement of the cam gear 84, then the center 
core push member drive lever 116 is rotated from its position shown in 
FIG. 10 in a clockwise direction in FIG. 10, so that, as shown in FIG. 10, 
the engagement between the center core push member drive lever 116 and the 
end portion 66A of the lever 66 is removed to thereby move the lever 66 in 
a downward direction. This causes the center core push portion 67 to move 
apart from the center core 14, thereby completing the center core push 
operation. This state is shown in FIG. 11, in which the regulation plate 
52 is set and thus the magnetic recording or reproducing operation is 
possible. 
If the cam gear 84 is rotated further and thus the slide plate 96 is moved 
in the left direction in FIG. 9, then the regulation plate drive lever 106 
is gradually rotated clockwise about the pin 108 against the energizing 
force of the spring 109 to cause the tip end portion 106A of the 
regulation plate drive lever 106 to move up the end portion 50A of the 
regulation plate holder 50, as shown in FIG. 12. As a result of this, 
while the cover 28 is open and the magnetic recording or reproducing state 
is not ready, the regulation plate 52 stands apart from the magnetic disc 
12 to eliminate the possibility that the regulation plate 52 may produce 
any pressure traces on the magnetic disc 12. 
In order to open the cover 28 after the magnetic recording or reproducing 
operation is completed, the cam gear 84 is rotated to move the slide plate 
96 in the right direction in FIG. 9. As a result of this, the lock lever 
126 is rotated counterclockwise about the pin 128 as shown in FIG. 13 to 
remove the engagement between the lock piece 126A of the lock lever 126 
and the projection piece 29A of the cover 28, so that the cover 28 can be 
opened by a spring which is not shown. 
Next, description will be hereunder given of another embodiment of a rotary 
magnetic disc device according to the present invention in connection with 
FIGS. 14 through 17. 
FIG. 14 is a front view of the main portions of the present rotary magnetic 
disc device and corresponds to FIG. 9 mentioned above. FIGS. 15 through 17 
are views obtained by observing the same device from behind FIG. 14, 
respectively illustrating the operation states of the slide plate 96. This 
second embodiment is different from the above-mentioned first embodiment 
in that the center core push operation can be performed as many times as 
required independent of the closing operation of the cover 28. In other 
words, in place of the above-mentioned center core push member drive lever 
116, there are provided a center core push member drive lever 116A and a 
center core push lever 119. Since other component parts in the second 
embodiment are the same as in the before-mentioned embodiment, they are 
given the same references and the detailed description thereof are omitted 
here. 
The center core push member drive lever 116A is constructed substantially 
in the same shape with the above-mentioned center core push member drive 
lever 116 (see FIG. 10), however, the drive lever 116A is not provided 
with a projection portion to push against the end portion 66A of the lever 
66 of the center core push member 60 as in the drive lever 116. 
On the other hand, the center core push lever 119 is rotatably supported 
through the pin 119A by the device main body 24 and is provided with an 
oblique groove 119B which the pin 120 of the drive lever 116A is fitted. 
The projection portion 119C of the center core push lever 119 is, as shown 
in FIG. 10, in contact with the end portion 66A of the lever 66. 
Therefore, if the drive lever 116A is rotated clockwise about the pin 118 
in FIG. 15 due to the movement of the slide plate 96, then the center core 
push lever 119 is rotated counterclockwise due to the action of the 
oblique groove 119B to push up the end portion 66A of the lever 66, with 
the result that the center core push portion 67 pushes against the center 
core 14 of the magnetic disc 12. 
Now, we will describe the operation of the second embodiment of the rotary 
magnetic disc device according to the invention that is constructed in the 
above-mentioned manner. 
At first, in the state shown in FIG. 1 in which the rotary magnetic disc 
device is open, the magnetic disc pack 10 is inserted into the pack holder 
26. When inserted into the pack holder 26, the magnetic disc pack 10 is 
guided and inserted into the two side end portions of the pack holder 26. 
After the magnetic disc pack 10 has been completely inserted into the pack 
holder 26, if the cover 28 is pushed down toward the device main body 24, 
then the center core 14 is mounted to the drive shaft 32 and at the same 
time the switch operation lever 138 is rotated by the front edge 29 of the 
cover 28 so that the switch 144 is operated. This state is shown in FIG. 
15. Next, the front edge 29 of the cover 28 is secured by the lock piece 
126A. 
Then, the second drive source 70 is operated: the rotational force of the 
second drive source 70 is transmitted via the worm 72, worm gear 74 and 
drive shaft 76 to the gear 78; and, the rotational force of the gear 78 is 
in turn transmitted via the gears 80, 82 to the cam gear 84. When the cam 
gear 84 is thus rotated, the slide plate 96 is moved in the right and left 
direction in FIG. 14 by the cam groove 94 in the cam gear 84. 
At first, when the slide plate 96 is moved left in FIG. 14 by means of the 
rotational movement of the cam gear 84, then the drive lever 116A is 
rotated clockwise in FIG. 15 from its position shown in FIG. 15. By means 
of the rotational movement of the drive lever 116A, the center core push 
lever 119 is rotated counterclockwise about the pin 119A to push up the 
end portion 66A of the lever 66, with the result that the center core push 
portion 67 pushes against the center core 14 toward the drive shaft 32, 
that is, it performs the center core push operation. This state is shown 
in FIG. 16. 
At the same time, when the slide plate 96 is moved left in FIG. 14, then 
the regulation plate drive lever 106 is also rotated clockwise gradually 
about the pin 108 against the energizing force of the spring 109 and, as a 
result of this, as shown in FIG. 16, the tip end portion 106A of the 
regulation plate drive lever 106 pushes up the end portion 50A of the 
regulation plate holder 50 to move the regulation plate 52 apart from the 
magnetic disc 12 so as to eliminate the possibility that the regulation 
plate 52 may leave any pressure traces on the magnetic disc 12. 
Then, if the cam gear 84 is rotated in the reverse direction to move the 
slide plate 96 right in FIG. 14, then the drive lever 116A is rotated 
counterclockwise from its position shown in FIG. 16. As a result of this, 
the center core push lever 119 is rotated clockwise about the pin 119A to 
thereby move down the end portion 66A of the lever 66, so that the the 
center core push portion 67 is moved apart from the center core 14. 
At the same time, when the slide plate 96 is moved right in FIG. 14, then 
the regulation plate drive lever 106 is rotated counterclockwise from its 
position shown in FIG. 16 to move down the end portion 50A of the 
regulation plate holder 50, with the result that the regulation plate 52 
can be set at the magnetic recording/reproducing position. This state is 
shown in FIG. 17. 
In order to open the cover 28 after the magnetic recording/reproducing 
operation is completed, the cam gear 84 is rotated to thereby move the 
slide plate 96 in the right direction in FIG. 14. As a result of this, the 
lock lever 126 is rotated, as shown in FIG. 15, counterclockwise about the 
pin 128 to remove the engagement between the lock piece 126A of the lock 
lever 126 and the projection piece 29A of the cover 28, so that the cover 
28 can be opened by a spring which is not shown. 
As has been described hereinbefore, according to the rotary magnetic disc 
device of the invention, the unlocking of the cover, the removal of the 
center core pushing operation and the retreat of the regulation plate can 
be performed by use of a single rotative drive source, so that the rotary 
magnetic disc device can be construced in a compact manner. 
It should be understood, however, that there is no intention to limit the 
invention to the specific forms disclosed, but on the contrary, the 
invention is to cover all modifications, alternate constructions and 
equivalents falling within the spirit and scope of the invention as 
expressed in the appended claims.