Compression system for microfiche files and the like

A system for controllably compressing a plurality of microfiche in a file tray comprises a flat compressor having a rigid upper transverse portion and a flexible, resilient lower transverse portion. A mounting mechanism mounts the compressor to a pair of rails extending lengthwise of the tray on either side of the microfiche for sliding motion lengthwise of the holder and permits the compressor to be inclined for access to the units. Cam means on the mounting mechanism releasably clamp the mounting mechanism to the rails when the compressor is rotated into a vertical position.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to file systems, and especially to trays, drawers, 
and other holders for filing individually removable microfiche and the 
like. More particularly it relates to means for releasably compressing the 
microfiche files in such holders for compact storage. 
2. Prior Art 
Typically, microfiche, microfilm aperture cards, computer floppy discs, and 
the like are stored in rigid open-top trays or drawers. Various systems 
have been devised for use with such trays and drawers to facilitate the 
manual insertion and removal of the individual information bearing units. 
U.S. Pat. Nos. 3,114,459 to Kersting and 3,347,393 to Frey are examples of 
such systems. Generally these systems incorporate means for applying force 
to compress some or all of the units into compact packs when they are not 
in use. 
In some of these devices the compression means are adapted to be inclined 
at an angle to an imaginary vertical plane as well as being moveable 
longitudinally of the file tray or drawer to afford the user easy access 
to the individual units. 
Some compressors of this type take the form of rigid end plates mounted for 
rotation about a horizontal axis extending transversely of the tray or 
drawer. Others employ one or more transversely mounted rigid tracks or 
railss adapted for movement longitudinally of the holder. 
While these prior art compression mechanisms serve their intended purposes 
more or less satisfactorily, they are not without deficiencies. Some do 
not furnish sufficient compressive force to retain the individual units in 
place in the event the tray or drawer is accidentally upset. Some furnish 
adequate restraining force, but are subject to inadvertent release with 
potentially catastrophic results. Most of them require the use of two 
hands for their operation, and even with the use of both hands, generally 
afford the user little control over the amount of force exerted against 
the individual units. In the case of systems utilizing the compressing 
means for fanning or separating the individual units, this lack of precise 
control prevents the user from taking full advantage of the system's 
capability. 
A number of filing systems provide means, such as embossments formed on 
segregators positioned between the individual units, for fanning or 
separating the units and enabling the user to examine their contents 
visually without removing them from the tray or drawer. U.S. Pat. No. 
3,913,250 to Arthur T. Spees, and my U.S. Pat. No. 4,231,175 are 
illustrative of systems of this type. Such systems likewise generally 
include means for compressing the information bearing units, and, not 
surprisingly, these suffer from similar deficiences. 
In an effort to design an improved compression mechanism for my patented 
file system, I developed and tested a compressor assembly comprising two 
rigid rectangular plates joined at their respective lower and upper edges 
by means of a piano hinge and maintained in planar alignment by means of a 
torsion spring mounted to the hinge pin. Mounting means secured to the 
side edges of the upper plate near its lower end permitted the "split" 
compressor to be mounted to a pair of axially aligned rods attached to the 
inside of the side walls of a file drawer for rotation about an imaginary 
horizontal axis transverse to the drawer. 
The mounting means were designed to clamp to the supporting rods when the 
compressor was in a vertical position, and to permit the entire assembly 
to slide longitudinally of the drawer on the rods when the compressor was 
rotated out of the vertical plane. 
In principle, sliding the compressor toward, say, a set of microfiche 
standing at one end of the drawer would bring the bottom edge of the lower 
plate into contact with the lower portion of the closest microfiche. 
Advancing the compressor further would urge the lower edges of the 
microfiche together. 
When the force required to overcome the collective resistance offered by 
the individual units exceeded the torque exerted by the torsion spring, 
the lower plate would rotate about the axis of the piano hinge until the 
face of the lower plate abutted the face of the closest fiche. Still 
further advancement of the compressor would cause the lower plate to urge 
the fiche successively into vertical alignment and then into compression. 
At that point the lower plate of the compressor would be aligned vertically 
as well, and continued advancement of the compressor would cause the upper 
plate to rotate about the piano hinge axis into vertical alignment with 
the lower plate, thereby applying maximum compressive force to the 
compacted microfiche and simultaneously locking the compressor assembly in 
place. 
In actuality, however, the hinged compressor proved to have certain 
drawbacks. Notably, for reasons not entirely clear, but probably 
associated with the nature of torsion springs, the action of the assembly 
was neither as fluid or as precisely controllable as had been anticipated. 
In an attempt to overcome these deficiencies I developed and tested a 
compressor consisting of a thin flexible resilient sheet of plastic 
material fastened by means of rivets to a rigid backing plate which 
extended across the upper two thirds of the sheet and served as a 
stiffener. As in the earlier assembly, self-locking mounting means secured 
to the rigid plate near its lower end supported the compressor on a pair 
of rails and provided for both longitudinal movement and rotation of the 
compressor. 
While this construction was an improvement over the earlier one, it still 
suffered, albeit to a lesser extent, from the previously mentioned 
deficiencies encountered with the split compressor. Apparently, the 
resilient strip joined to the rigid plate with a portion of the strip 
extending beyond the plate was the functional equivalent of a pair of 
rigid plates joined by a hinge and retained by a torsion spring. 
Based on the foregoing experience I have now constructed a compressor which 
avoids the problems encountered with the earlier designs. With this new 
compressor, the invention disclosed here represents a novel compression 
system that can be adapted advantageously to virtually any microfiche 
holder and that avoids the deficiencies mentioned earlier which are 
inherent in the prior art file systems. 
One object of the invention is to provide compression means capable of 
applying sufficient force to the contents of the tray or drawer to retain 
the contents in the tray or drawer even if it should be upset. 
Another object is to provide a compression mechanism for file trays and 
drawers which can be operated readily with one hand. 
Yet another object is to provide compression means which allow the user to 
control the force applied to the individual units smoothly and with 
precision regardless of the number of units or their location in the tray 
or drawer. 
Still another object is to provide compression means which will not 
interfere with the operation of prior art fanning and separating systems 
of the type previously mentioned. 
Other objects and features of the invention and its advantage over the 
prior art will become apparent to the reader from the following detailed 
description of several of its preferred embodiments as illustrated in the 
accompanying set of drawings. 
BRIEF DESCRIPTION OF THE INVENTION 
The preferred embodiment of the present invention differs from my two 
previously mentioned earlier systems in the construction of the 
compressor. As in those embodiments, the compressor is mounted by 
self-locking mounting means to a pair of elongated parallel longitudinally 
aligned rails for controlled rotation about a transverse axis and sliding 
motion longitudinal of the tray or drawer. 
In this instance, however, rather than being formed in two sections joined 
at their respective lower and upper edges, the compressor comprises a 
single plate of resilient material, preferably of reduced thickness (and 
thus greater resilience) across the full width of its lower portion. 
This distinction over the prior compressor construction, while seemingly 
slight, has been found to make an unexpected, marked improvement in the 
operation of the compressor assembly and allows the assembly to satisfy 
all of the aforementioned objects.

DETAILED DESCRIPTION OF THE INVENTION 
The file tray 11 illustrated in FIG. 1 is formed with end walls 12, 13, 
side walls 14, and bottom 15 adapted to receive and hold a deck of 
flexible microfiche cards 16 in a row, one behind another. Typically such 
cards are rectangular and have top, bottom, and side edges. Often they are 
provided with flexible protective jackets. In some filing systems they are 
separated by embossed segregators or index cards. My invention will work 
equally well with any and all of these configurations. 
An adjustable retaining plate 18, which is moveable longitudinally of tray 
11, serves as a backstop for cards 16 and allows the user to position them 
within the tray 11 for convenient viewing and manipulation. 
The invention comprises three elements: the compressor 21; a pair of 
elongated parallel rails 22, in this instance a pair of rigid steel rods 
attached at their respective ends to the end walls 12, 13 of tray 11 and 
extending longitudinally of tray 11 along the sides of fiche 16; and 
mounting mechanism 23 by means of which compressor 21 is mounted to rails 
22. 
Compressor 21 is a unitary, unbroken sheet of suitable material, such as 
polypropylene, polyethelene, polyvinyl plastic, or the like. Preferrably, 
the upper transverse portion 24 of compressor 21 is of sufficient 
thickness to be substantially rigid. The lower transverse portion 25 is of 
such thickness as to be resilient throughout its width. 
Referring to FIGS. 2-4, mounting mechanism 23 comprises a support bracket 
27 secured to compressor 21 near the lower edge of rigid upper portion 24 
thereof by conventional means, such as rivets 28, and a slide bracket 29. 
A channel 31 formed in the upper end of slide bracket 29 is adapted to 
receive and retain rail 22 in snug engagement for smooth, unimpeded 
sliding axial movement thereon. 
Support bracket 27 and slide bracket 29 are formed of Nylon or other 
suitable durable resilient plastic material. 
A projection formed on the outer end 34 of support bracket 27 serves as an 
axle 33. Axle 33 is journalled through the wall of slide bracket 29 and 
permits compressor 21 to be rotated about an imaginary axis transverse to 
tray 11 and perpendicular to its side walls 14. Compressor 21 is offset 
from this axis of rotation by the spacing separating the plane containing 
compressor 21 from the axis of axle 33. 
A slot 35 formed in axle 33 allows its enlarged head 36 to be inserted 
through opening 37 in the wall of slide bracket 29, and on expansion of 
axle 33 head 36 retains slide bracket 29 securely mounted to support 
bracket 27. 
Mounting means 23 includes clamping means 38 which, as will be explained, 
serves a dual purpose. In this embodiment clamping means 38 takes the form 
of an upwardly directly arm 39 formed on the outer end 34 of support 
bracket 27. Arm 39 has a groove 41 in its upper end, 
As seen most clearly in FIGS. 2 and 3, a boss 43 formed on the inner face 
of slide bracket 29 limits the rotation of support bracket 27 in one 
direction to a first position in which compressor 21 is vertical. In this 
first position, shown in FIG. 2, the walls of groove 41 engage the 
underside of rail 22 in clamping frictional contact, effectively locking 
compressor 21 in the vertical first position and preventing slide bracket 
29 from moving axially of rail 22. 
The rotation of arm 39 around axle 33 in the direction away from microfiche 
16 releases its frictional exgagement with rail 22. Face 45 on slide 
bracket 29 serves as a stop for arm 39 and limits the rotation of 
compressor 21 to a predetermined second position, as shown in FIG. 3. 
By virtue of this construction the mounting mechanism 23 affords compressor 
21 freedom of both rotational and longitudinal movement in all but its 
vertical first positon, and in that position mechanism 23 serves as a 
releasable clamp, resisting both rotational and longitudinal movement of 
compressor 21. 
FIGS. 5A-5C illustrate the operation of a filing system embodying the 
invention. As seen in FIG. 5A, manually operated sliding clamps 47 permit 
retaining plate 18 to be moved along rails 22 to position the deck of 
microfiche cards 16 in tray 11 for easy reach by the user. 
With compressor 21 inclined in the aforementioned second position and 
spaced from plate 18, as shown in FIG. 5A, fiche 16 may readily be 
"fanned" for visual inspection or removal. The spacing of compressor 21 
from plate 18 determines the angular separation of the fiche. By grasping 
the exposed upper portion 24 of compressor 21, the user may move the 
compressor in either direction along rails 22 with ease, thereby 
controlling the the distance between the upper edges of successive fiche. 
Sliding compressor 21 in the direction indicated by arrow 49 compresses the 
lower ends of fiche 16 and presents the lower portion 25 of compressor 21 
with a resisting force. Further motion in the same direction against this 
force causes the resilient lower portion 25 of compressor 21 to bend 
downwardly, and simultaneously urges compressor 21 to rotate about axle 33 
toward a more nearly vertical position, as shown in FIG. 5B. 
As seen in FIG. 5B, while the force exerted by the lower portion 25 of 
compressor 21 has compressed the fiche 16 into a fairly compact deck, 
since the upper portion 24 of compressor 21 is not yet vertical, arm 39 
has not yet engaged rail 22. Thus sliding bracket 29 is still freely 
moveable and compressor 21 is still freely rotatably. The user thus 
continues to have complete control over the positioning of compressor 21, 
and therefore, over the precise amount of compressive force applied to the 
deck of fiche. 
In FIG. 5C compressor 21 has been rotated into its previously described 
vertical position. Here arm 39 is in clamping engagement with rail 22, and 
slide bracket 29 and arm 39 are immobilized. That is, the configuration of 
groove 41 at the top of arm 39 offers a resilient force in opposition to 
rotation of arm 39 which effectively locks the entire slide bracket 
assembly in place. The geometry and characteristics of the material of the 
assembly, and particularly of arm 39, determine the amount of force the 
user must exert at the upper edge of compressor 21 to release the 
assembly. 
FIG. 6 is illustrative of one of a number of alternative embodiments of my 
invention. In this construction the rail takes the form of an elongated 
"C"-shaped channel 51. The mounting mechanism comprises a slide assembly 
52 which includes a pair of plates, here in the form of disks 54, 55. 
Disk 54 is adapted for sliding motion within channel 51 and is connected to 
disk 55 by a spacer 56. Spacer 56 passes through the slot 57 in the side 
of channel 51 and has a cam-shaped cross-section which is adapted for 
frictional clamping engagement of the edges 58 of slot 57 when support 
bracket 59 and compressor 61 are in a vertical position. Spacer 56 is 
configured to limit the rotation of compressor 61 in one direction to the 
vertical position, and in the opposite direction to some predetermined 
inclined position. 
While I have described my invention in terms of alternative preferred 
embodiments, it is not to be construed as limited to those embodiments, 
and they are to be regarded as illustrative rather than restrictive. It is 
my intention by this specification to cover any and all variations of the 
examples I have chosen for purposes of the disclosure, which do not depart 
from the spirit and scope of the following claims.