Lock for diskette drive

Disclosed is a lock for diskette drive suitable for inserting into and locking up a disk slot of said diskette drive to prevent any unauthorized data reading, writing, and copying, mainly including a top and a bottom covers closed together to contain a springy plate and a push plate therebetween. The push plate is disposed below the springy plate and is always pushed backward by a first compression spring. The bottom cover has a back recess into which a lock body is positioned. A spindle extends through the lock body for a plurality of lock pins to hang thereon. Front ends of the lock pins project through holes on the lock body to extend into a sliding groove formed on a movable member when a key card is inserted into a card slot on the lock body. The movable member is positioned between the bottom cover and the lock body and over the lock body and is always pushed by a second compression spring to an outward position and has a projection provided to one side thereof. When the key card is inserted into the card slot and the push plate is pushed into the top and the bottom covers with a dent thereof engaging with the projection of the movable member, and then the key card is pulled out, the push plate is locked in place and lift a front hook portion of the springy plate to contact with an inner edge of the disk slot and be retained therein. When the key card is inserted into the card slot again and the movable member is pushed laterally inward, the projection of the movable member disengages from the dent of the push plate, allowing the latter to move backward and the front hook portion of the springy plate to lower down and disconnect from the disk slot.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a lock for diskette drive mainly including 
a top cover, a bottom cover, and a springy plate and a push plate disposed 
between the top and the bottom covers. When a key card is inserted into a 
card slot and the push plate is pushed inward, the springy plate is lifted 
to engage with and be retained by the diskette drive, and a projection on 
a movable member is engaged into a dent formed on the push plate to retain 
the latter in a locked position. The bottom cover has a back recess to 
receive a lock body therein. When the key card is inserted into the card 
slot while the push plate is in the locked position, and the movable 
member is laterally pushed inward, the projection of the movable member 
disengages from the dent on the push plate, allowing the push plate to 
move back and the springy plate to lower down to disengage from the 
diskette drive. 
2. Description of the Prior Art 
For most of the diskette drives connected to a computer for a diskette to 
read data from the computer, there is not any security measure to protect 
such data from being read without authorization. Any user can simply 
insert a floppy into the drive. The drive might very possibly be damaged 
due to improper operation of the drive, and the stored data are arbitarily 
retrieved and copied without authorization. This has long been a confusion 
to both the manufacturers and the consumers. 
The presently available locks for diskette drives are very rough in their 
structure. FIG. 1 illustrates a conventional locking means for diskette 
drive. The locking means mainly includes a lock 7 which has an insertion 
plate 71 connected to a front of it. The insertion plate 71 has a 
thickness suitable for inserting into the front slot of a disk drive. A 
notch 72 of suitable dimensions is formed on the insertion plate 71 
between it and the lock 7, so that a shaft 73 extending forward from the 
lock 7 may extend into the notch 72 and causes a rectangular end plate 74 
connected to a front end of the shaft 73 to turn. When a key 75 inserted 
in the lock 7 is turned, the shaft 73 and accordingly, the end plate 74 
are turned along with the key 75. The end plate 74 may be in a horizontal 
or unlocked position or in a vertical or locked position. When the end 
plate 74 is turned to the vertical or locked position as shown in FIG. 1, 
its upper and lower ends will be retained by an upper and a lower inner 
surface of the insertion slot of the diskette drive. Thereby, the 
insertion slot of the diskette drive is closed by the lock 7 and no 
diskette can be inserted into the drive for any read or write operation. 
On the other hand, when the end plate 74 is turned to the horizontal or 
unlocked position, the insertion plate 71 along the whole lock 7 can be 
pulled out of the drive from the slot, leaving the slot open and allowing 
a diskette to be inserted thereinto. 
The major disadvantage existed in such conventional lock for diskette drive 
is that the rectangular end plate 74 in the vertical or locked position 
provides only very weak locking structure and function. When the lock 7 is 
pulled outward by tools, the normally metal made end plate 74 would 
usually destroy the edges of the disk slot which is usually made of 
plastic material and finally be entirely pulled out and loses its security 
function. A diskette can still be inserted into the slot even the latter 
has been damaged at its upper and lower edges and data can still be read 
from or written into the diskette inserted into the slot. 
It is therefore desirable to develop a lock for diskette drive to provide 
enhanced structure and performance. 
SUMMARY OF THE INVENTION 
A primary object of the present invention is to provide a lock for diskette 
drive which may securely lock the diskette drive to prevent others from 
using, damaging or copying data stored in the computer. 
Another object of the present invention is to provide a lock for diskette 
drive which is simple in structure and easy to operate. 
The lock for diskette drive according to the present invention includes a 
notched top cover and a notched bottom cover engaged with each other to 
contain a springy plate therebetween to lock a diskette drive. A push 
plate is disposed below the springy plate. By means of compression springs 
and a movable member having a projection, the push plate can be forced to 
push the springy plate to a lifted position to lock the diskette drive. A 
lock body is disposed to a back portion of the bottom cover. The lock body 
has a card slot for a key card to insert thereinto. The lock body is 
provided therein with a plurality of lock pins which each includes a hook 
portion and a lug portion. When a key card having through holes is 
inserted into the lock body via the card slot and then be withdrawn 
therefrom, the lug portions of the lock pins shall cause front ends of the 
lock pins to be located in a sliding groove of the movable member, so that 
the movable member may be depressed to bring its projection to disengage 
from a dent of the push plate and thereby unlock the diskette drive, or, 
the push plate may be depressed to bring its dent to engage with the 
projection of the movable member and thereby lock the diskette drive.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Please refer to FIGS. 2, 2A, 3, 4, and 5. The present invention is a lock 
for diskette drive and mainly includes a top cover 1 and a bottom cover 2 
which can be closed together to form a complete body. Notches 101 and 201 
are respectively formed on the top cover 1 and the bottom cover 2 at a 
front central portion thereof. A curved springy plate 13 is disposed 
between the top cover 1 and the bottom cover 2 by engaging its rear 
through holes 131 with fixing pins 11 provided on an inner side of the top 
cover 1 near the notch, such that a front hook portion of the springy 
plate 13 projects forward from the notches 101, 201. When the springy 
plate 13 is pivotally lifted, the hook portion shall hook against an inner 
edge of a disk slot of a diskette drive 6 (not shown). The top cover 1 
further has a pair of rails 10 provided on the inner side thereof for a 
push plate 14 to move forward or backward therebetween. A boss 12 is 
centered between the rails 10. The push plate 14 has an opening 141 formed 
at a front central portion thereof. The opening 141 has a widened front 
portion for the fixing pins 11 to upward project therefrom and a narrowed 
rear portion for receiving a first compression spring 24 therein. The push 
plate 14 further has a dent 142 formed at one side near a rear end 
thereof. One end of the first compression spring 24 presses against the 
boss 12 and the other end against a central channel 21 of the bottom cover 
2, which will be described below. The push plate 14 is located below the 
springy plate 13. When the push plate 14 is pushed to move forward between 
the rails 10, a front end of the push plate 14 shall lift the front hook 
portion of the springy plate 13. And, when the push plate 14 is pushed by 
the first compression spring 24 to move backward between the rails 10, the 
front hook portion of the springy plate 13 is allowed to lower. The first 
compression spring 24 shall enable the push plate 14 to normally return to 
a rear position relative to the top cover 1. 
The bottom cover 2 is a substantially T-shaped member for connecting to a 
lower side of the top cover 1, as shown in FIG. 4. At a rear end of the 
bottom cover 2 opposite to the front central notch 201, that is, at the 
transverse portion of the bottom cover 2, there is a recess 20 having only 
three sidewalls with a backwark opening. The recess 20 is provided at 
inner surfaces of two lateral sidewalls with a bar 23 each for locating a 
lock body 3 thereat. A slot 22 is formed at one outer sidewall of the 
recess 20 so that a movable member 4 can laterally move in a course 
defined by the slot 22. 
The lock body 3 is received in the recess 20 of the bottom cover 2. The 
lock body 3 includes a U-shaped seat 31 at an upper portion thereof. A 
reverse U-shaped through hole 32 extends the length of the U-shaped seat 
31 at a lower portion thereof, such that a spindle 311 can be extended 
through the through hole 32 for a plurality of lock pins 35 to hang 
thereon side by side. The lock pin 35 each includes a hook portion 351 and 
a lug portion 352. The lock pin 35 is hung on the spindle 311 by hooking 
its hook portion 351 on the spindle 311, such that a front end of the lock 
pin 35 can freely move up or down about the spindle 311. A series of 
through holes 33 are spaced in parallel along the lock body 3, such that 
the front ends of the lock pins 35 and the lug portions 352 thereof are 
separately supported on and project forward from the through holes 33. The 
through hole 32 forms two long openings on two lateral ends of the lock 
body 3 to just engage with the two bars 23 of the recess 20 of the bottom 
cover 2, so that the lock body 3 is fixed in the recess 20. A card slot 30 
is provided to a lower portion of the lock body 3 for a key card 5 to 
insert thereinto. The key card 5 is formed with through holes 51 to engage 
with the lug portions 352 of the lock pins 35. The spindle 311 is fixed in 
place by inserting it into a space defined by the U-shaped seat and the 
reverse U-shaped through hole 32 extending through the lower portion of 
the former. 
The movable member 4 has a slightly sunk portion 41 formed near an inner 
end thereof for supporting a rear portion of the push plate 14 and 
allowing the same to move inward or outward over there, a projection 42 
formed at one inner corner of the sunk portion 41 for detachably engaging 
with the dent 142 on the push plate 14, a push button 43 connected to an 
outer end of the movable member 4 opposite to the sunk portion 41, a guide 
portion 44 for engaging into the slot 22 formed on one outer sidewall of 
the recess 20 to limit the travel of the movable member 4, a plurality of 
parallely arranged upper teeth 45 and lower teeth 46 pairs formed at a 
lower rear part of the movable member 4 below the sunk portion 41, and a 
horizontally extended sliding groove 47 formed between the upper teeth 45 
and the lower teeth 46 for receiving the forward projected front end of 
the lock pins 35 when the key card 5 is inserted into the card slot. To 
enable the movable member 4 to normally return to an laterally outward 
position, a second compression spring 34 is disposed between the inner end 
of the movable member 4 opposite to the push button 43 and an inner end 
surface of the recess 20 of the bottom cover 2 abutting against the inner 
end of the movable member 4, so that the movable member 4 is always 
laterally sprung outward. 
It is very easy to assemble the lock for diskette drive according to the 
present invention. When assembled, as shown in FIGS. 4 and 5, the springy 
plate 13 forward projects into the front central notches 101, 201 of the 
top cover 1 and the bottom cover 2, respectively. The push plate 14 is 
located below the push plate 13. The first compression spring 24 always 
pushes the push plate 14 backward. The second compression spring 34 always 
pushes the movable member 4 laterally outward so that the projection 42 of 
the movable member shall extends into and firmly engage with the dent 142 
of the push plate 14 when the latter passes by the projection 42. The 
movement of the movable member 4 depends on whether the front ends of the 
lock pins 35 projected from the through holes 33 of the lock body 3 are 
located in the sliding groove 47 between the upper and the lower teeth 45, 
46 inside the movable member 4, and on whether the key card 5 is inserted 
into the card slot 30. 
Please refer to FIG. 6 in which a lock according to the present invention 
in an unlocked state is shown. As shown, the push plate 14 is not pushed 
into the top and the bottom covers 1, 2 and the springy plate 13 is not 
lifted by the push plate 14. At this point, the projection 42 of the 
movable member 4 at one end of the sunk portion 41 (not shown) is not 
engaged into the dent 142 of the push plate 14 and is therefore not pushed 
laterally outward by the second compression spring 34. 
In FIG. 7, the lock of the present invention in a locked state is shown. 
The push plate 14 is pushed into the top and the bottom covers 1, 2 to 
lift the front hook portion of the springy plate 13. Meanwhile, when the 
dent 142 passes by the projection 42 of the movable member 4, the second 
compression spring 34 immediately pushes the movable member 4 laterally 
outward and causes the projection 42 to extend into and engage with the 
dent 142, locking the push plate 14 in a forward inserted position. 
Please now refer to FIGS. 8 and 9 for the operation of the lock of the 
present invention. When the lock is inserted into the diskette drive 6 
while it is in the unlocked state, the push plate 14 is not pushed inward 
and the springy plate 13 is not lifted to contact with an inner edge of a 
disk slot of the diskette drive 6. When the key card 5 is inserted into 
the card slot 30, it brings the front end portions of the lock pins 35 to 
project out of the holes 33 and locate in the sliding groove 47 on the 
movable member 4. To lock the disette drive 6, push the push plate 14 
inward to force the front hook end of the springy plate 13 to lift while 
the dent 142 engages with the projection 42 of the movable member 4. The 
engagement of the projection 42 into the dent 142 causes the movable 
member 4 to shift leftward relative to the bottom cover 2 due to the 
spring force of the second compression spring. 34. Since the lock pins 35 
are freely hung on the spindle 311 by hooking the hook portion 351 thereof 
to the spindle 311, the insertion of the key card 5 shall push the lug 
portions 352 and causes the front ends of the lock pins 35 to locate in 
the sliding groove 47 of the movable member 4, the movable member 4 with 
the engagement of the projection 42 into the dent 142 is allowed to be 
shifted leftward by the second compression spring 34. At this point, the 
key card 5 is pulled out of the card slot 30 so that the lug portions 352 
are no longer limited by the through holes 51 on the key card 5. At this 
point, the lug portions 352 shall be released to locate in grooves at two 
sides of the upper teeth 45 or the lower teeths 46 and the movable member 
4 is prevented from moving rightward. 
To unlock the diskette drive 6, first insert the key card 5 into the card 
slot 30 so that the lug portions 352 of the lock pins 35 just fall into 
the through holes 51 on the key card 5 and the front end of the lock pins 
35 locate in the sliding groove 47 again. Then, the push button 43 of the 
movable member 4 is depressed to disengage the projection 42 from the dent 
142 on the push plate 14, as shown in FIG. 6. At this point, the first 
compression spring 24 shall immediately push the push plate 14 backward, 
allowing the front hook portion of the springy plate 13 to lower down and 
no longer contacts with the inner edge of the disk slot of the diskette 
drive 6. Thereby, the whole lock for diskette drive can be pulled out of 
the drive 6. The operation is easy and convenient.