Technical Field

This invention relates to apparatus for holding printed circuit cards.

Background Art

U.S. Patent No. 3,767,974 discloses apparatus for holding printed circuit cards wherein the cards ride in individual slots in a multiple card cage. During insertion, a card rides freely until the output conductors on the card confront the receiving connector block at the rear of the cage. At this point, cylindrical bosses on corresponding upper and lower levers contact a reinforced edge of the card, and pivoting action of the levers drives the card into a fully inserted position. Rotation of the levers in - - the opposite direction brings another cylindrical boss on each lever into engagement with the inner surface of the reinforced edge, thereby extracting the card conductors from engagement with the connector block, whereafter the card can be freely removed from the cage.

The known apparatus has the disadvantage that forces acting on the card as the connectors are disengaged may crack or otherwise damage the card as it is being removed from engagement.

Disclosure of the Invention

It is an object of the present invention to provide apparatus for holding printed circuit cards, wherein the aforementioned disadvantage is alleviated.

Therefore, according to the present invention, there is provided apparatus for holding printed circuit cards, characterized by: a card cassette having mounted therein a printed circuit card; a housing adapted-to selectively receive said

cassette; and a pair of first and second levers mounted on said housing and adapted to engage with said cassette, said first and second levers being rotatable in respective first directions to engage respective upper and lower portions of said cassette to move said cassette into said housing and being rotatable in respective second directions to respectively engage said upper and lower portions to move said cassette out of said housing.

Brief Description of the Drawings

One embodiment of the present invention will now be described by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a perspective view of a cabinet containing a card cage and showing a representative card cassette partially inserted into (or extracted from) the card cage and other card cassettes fully inserted into the card cage;

FIG. 2 is a perspective view of one of the card cassettes removed from the card cage of FIG. 1;

FIG. 3 is an exploded perspective view of the card cage of FIG. 1;

FIG. 4 is a partial side view showing upper and lower ejector levers respectively mounted on associated crosswires of the card cage of FIG. 3 and further respectively seated against associated ejector pins of a card cassette;

FIG. 5 is an exploded perspective view of the card cassette of FIG. 2;

FIG. 6 is a fragmentary view of one of the connectors 147 secured to the metal plate 23, taken from the perspective of line 6-6 of FIG. 5 in the direction of the arrows; and

FIG. 7 is a fragmentary view of a glide and an ejector lever in engaging relationship, taken from the perspective of line 7-7 of FIG. 4 in the direction of the arrows.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to FIG. 1 of the drawings, a cabinet 11 is shown containing a card cage 13 filled with a plurality of card cassettes 15χ . . . 15^ (not shown) mounted in parallel slots or channels (FIG. 3) of the card or cassette cage 13. Each of the card cassettes 15χ . . . 15^ is controllably inserted in, retained in or extracted from its associated channel by means of an associated pair of upper (U) and lower (L) card ejector levers. For the sake of clarity, only the card ejector levers 17τ j and 17IL for card cassette 15χ are shown. The card cassette 15χ is shown partially inserted into (or extracted from) the card cage 13 while the other ones of the card cassettes 152 • • • ¹⁵ N ^are fully retained therein by the associated pairs of card ejector levers (not shown) .

FIG. 2 shows the exemplary card cassettee 15ι removed from the card cage 13 of FIG. 1. As shown in FIG. 2, the card cassette 15χ includes an upper glide 19, a lower glide 21, a metal plate 23 and an I/O (input/output) bulkhead 25. Elements 19, 21, 23 and 25 form a cassette 27 for retaining a processor board or printed circuit card 29 (FIG. 5). The elements 19, 21, 23, 25 and 29 will be explained later in more detail in relation to FIG. 5.

Referring now to FIG. 3, an exploded perspective view of the card cage 13 of FIG. 1 is shown. The card cage 13 is comprised of side frames 31 and 33, upper and lower wire frame racks 35 and 37 and a back frame 39. Each of the wire frame racks 35 and 37 includes a plurality of parallel wires 41]_ - 41τ_]_ running from front to back, a plurality of parallel crosswires 43χ - 434 orthogonally disposed with respect to the wires 41τ_ - 41χχ, and crosspieces 45χ and 452 positioned parallel to the crosswires 43τ_ - 434 and respectively adjacent to the crosswires

43χ and 434. Each of the wires 41χ - 41χχ and 43χ - 434 has a 6.3mm (0.25) inch diameter. The spacing between the centers of adjacent ones of the wires 41ι - 41χχ in each of the racks 35 and 37 is 20mm (0.8 inch) .

The racks 35 and 37 are inverted from each other, such that the front ends of the wires 41χ - 41χχ in upper rack 35 are turned up over the crosswire 43χ in upper rack 35 while the front ends of the wires 41χ - 41χχ in lower rack 37 are turned down over the crosswire 43χ in lower rack 37. In addition, the crosswires 43χ - 434 and crosspieces 45χ and 45 °^ rack 35 are on top of the wires 41χ - 41χχ of rack 35, while the crosswires 43χ - 434 and crosspieces 45χ and 452 °£ rack 37 are on the underside of the wires 41χ - ⁴ 11 ^of rack 37.

In the assembly of the card cage 13, left-end portions 51-54 of the respective crosswires 43χ - 434 of upper rack 35 seat into associated holes 55 - 58 near the top of side frame 31, right-end portions 61 - 64 of the respective crosswires 43χ - 434 of upper rack 35 seat into associated holes 65 - 68 near the top of side frame 33, left-end portions 71 - 74 of the respective crosswires 43χ - 434 of lower rack 37 seat into associated holes 75 - 78 near the bottom of side frame 31, and right-end portions 81, 82, 83 and 84 (not shown) of the respective crosswires 43χ - 43 of lower rack 37 seat into associated holes 85 - 88 near the bottom of side frame 33.

The side frames 31 and 33 are rigidly held against the racks 35 and 37 by screws 91 which are passed through associated holes 93 in the side frames 31 and 33 and screwed into internally threaded holes 95 in both ends of each of the crosspieces 45χ and 452 of each of the racks 35 and 37. Screws (not shown) are then passed through holes 99 in the back frame 39 and screwed into internally threaded holes 100 of

flanged rear portions 101 of the side frames 31 and 33 to complete the assembly of the card cage 13.

After the card cage 13 has been completely assembled, it is inserted into the cabinet 11 (FIG. 1) and securely mounted thereto by means such as screws (not shown). Then the upper card ejector levers (not shown) respectively associated with the card cassettes 15χ - 15jj (where N = 10 in this case) are snapped onto the crosswire 43χ of the upper rack 35 (FIG. 3), respectively between associated adjacent ones of the wires 41χ - 41χχ in the rack 35. Similarly, the lower card ejector levers (not shown) respectively associated with the card cassettes 15χ - 15^ (where N = 10 in this case) are snapped onto the crosswire 43χ of the lower rack 36 (FIG. 3), respectively between associated adjacent ones of the wires 41χ - 41χχ in the rack 37.

Each of the upper and lower card ejector levers is preferrably made of nylon and is similar in configuration to each of the others. The configuration of these card ejector levers will be explained by now referring to FIG. 4, which specifically illustrates card ejector levers 17χu and 17χχ, for the card cassettes 15χ.

As shown in FIG. 4, each of the levers 17χg and 17χ£, includes a handle 105 at one end and a body 106 which includes an arcuate section 107 at the other end. The arcuate section 107 includes an opening 109 of slightly less than half a circle, a protuberance 111 adjacent to the opening 109 and a detent 113 adjacent to the protuberance 111.

The arcuate sections 107 of the levers 17χτj and 17 L are snapped over the respective crosswires 43χ of the upper and lower racks 35 and 37, causing the crosswires 43χ of the racks 35 and 37 to respectively seat into the associated openings 109 of the arcuate sections 107. As indicated before, the

lever 17χg is snapped onto the crosswire 43χ of the rack 35 between wires 41χ and 412 of the rack 35, while the lever 17XL is snapped onto the crosswire 43χ of the rack 37 between wires 41χ and 412 of the rack 37. The wires 41χ of the racks 35 and 37 are respectively shown in front of the ejector levers 17χg and 17x1,. However, only a segment of the wire 41χ of rack 37 is shown, so that the wire 412 can be shown (a portion of which is in phantom) behind the ejector lever 17χι,. Note that the levers 17χu and 17χj, are oppositely positioned from each other into the respective- crosswires 43χ of the racks 35 and 37. The operation of the levers 17χu and 17χL will be explained later.

It should be noted that a decal (not shown) made of magnetic strip tape is adhered to the handle 105 of each of the levers 17χu and 17χL to identify the associated card cassette, which in this case is card cassette 15χ (FIG. 2). Such decals also cause the handles 105 of the levers 17χg and 17χL to respectively adhere to top and bottom magnetic surfaces (not shown) of the cabinet 11 (FIG. 1) when the lever 17χu has been manually rotated upward around the wire 43χ of rack 35 in the direction of arrow 115rj and into a substantially horizontal position, and the lever 17χχ, has been manually rotated downward around the wire 43χ of rack 37 in the direction of arrow 115χ. and into a substantially horizontal position.

Referring now to FIG. 5, an exploded perspective view is shown of the card cassette 15χ of FIG. 2. As discussed before, the card cassette 15χ is comprised of upper glide 19, lower glide 21, metal plate 23, I/O bulkhead 25 and processor board or printed circuit card 29.

Each of the glides 19 and 21 is preferably made of nylon and has a substantially M-shaped configuration consisting of ribs 121, 122 and 123

which run the length of that glide. The glides 19 and 21 also contain slots 125 (as shown in the glide 21) for allowing air to flow therethrough. Ejector release pins 127 and 128 are passed through holes 129 at the front of each of the ribs 121-123 in the respective glides 19 and 21. These ejector release pins 127 and 128, which are used in the insertion, retention or extraction of a card cassette (such as the card cassette 15χ) into, in or from the card cage 13 (FIG. 1), will be discussed later.

After the ejector release pins 127 and 128 are inserted into the respective glides 19 and 21, the various components shown in FIG. 5 are assembled into the card cassette of FIG. 2, as discussed below.

The glides 19 and 21 are respectively seated into and attached to L-shaped brackets 131 and 133 at the top and bottom of the metal plate 23 by means of screws 135, which pass through associated holes 137 in the L-shaped brackets 131 and 133 and into associated internally-threaded holes 139 in the glides 19 and 21. Note that the glides 19 and 21 are inverted in position with respect to each other in order to seat into the respective brackets 131 and 133. Further note that each of the brackets 131 and 133 also contains slots 141 therethrough. In this manner air can freely flow through the glides 19 and 21 and their respective associated brackets 131 and 133.

If a memory sub-module 143 is to be used in the card cassette 15χ of FIG. 5, it is plugged into a plug 145 on the processor board 29 and then becomes a part of that processor board 29. The processor board 29 includes three connectors 147 mounted on the right- hand side of the board 29 and electronic circuitry 149 for receiving, processing, utilizing and outputting data and control signals.

The I/O bulkhead 25 is C-shaped and has three feet or tabs 151 along one side of its length, with a

hole 153 through each of the tabs 151. This bulkhead 25 contains connectors 155 for coupling to mating external connectors (not shown) to ultimately enable control signals and data to be received, processed and returned to external devices (not shown).

To assemble the bulkhead 25 to the processor board 29, the three tabs 151 of the bulkhead 25 are placed on top of the left hand side of the processor board 29, as shown in FIG. 5. Suitable nylon press-in units (not shown) are then pressed through the holes 153 in the tabs 151 of the bulkhead 25 and through coaxially aligned holes (not shown) in the processor board 29 to securely hold the bulkhead 25 to the processor board 29. The assembly of the bulkhead 25 and processor board 29 is then fitted into a recessed portion 157 of the metal plate 23 and against an inside surface 159 of the metal plate 23. Screws 161 are passed through holes 163 in tabs 165 of the metal plate 23 and into internally threaded holes 167 of the bulkhead 25 to complete the assembly of the card cassette 15χ.

It should be noted at this time that tips (not shown) of the nylon press-in units (not shown) protrude from the underside (not shown) of the processor board 29 to provide a nylon spacing between the processor board 29 and the inside surface 159 of the metal plate 23, so that the processor board 29 is physically separated from the metal plate 23.

The right-hand side of the processor board 29 is fastened to the metal plate 23 by way of pins (FIG. 6) which pass through holes 169 in the connectors 147 and into respective alignment holes 173 of the metal plate 23. Referring now to FIG. 6, a fragmentary view is illustrated of how one of the connectors 147 of FIG. 5 is secured to the metal plate 23 of FIG. 5.

Although the description of FIG. 6 is directed to the mounting of a portion of the right-

hand side of the processor board 29 to the metal plate 23 by way of only one of the holes 169 in one of the connectors 147 shown in FIG. 5, it should be understood that such description also applies to the mounting of the remainder of the right-hand side of the processor board 29 to the metal plate 23 by way of each of the rest of the holes 169 in the connectors 147 of FIG. 5.

As shown in FIG. 6, a grommet 171, preferrably made of neoprene or some other suitable material, is glued into an alignment hole 173 in the metal plate 23. A headed pin 175, preferrably made of steel, is passed through an associated hole 169 in the connector 147 and snapped into the grommet 171. An 0- ring 177 is then sealed into a recessed portion 179 around an end of the pin 175 and against a shoulder 181 of the grommet 171 to retain the processor board 29 in close proximity to the metal plate 23. The grommet 171, being made of neoprene or some other suitable resilient material, permits a slight flex to correct for any minor misalignment of the associated connector 147.

FIG. 7 is a fragmentary view of the engagement of the lower card ejector level 17χL (FIG. 4) and its associated glide 21 (FIG. 5), taken from the perspective of line 7-7 of FIG. 4 in the direction of the arrows. To better understand how the cassette 15χ (FIG. 2) is slideably mounted in the card cage 13 (FIG. 1), both of FIGS. 4 and 7 will now be referred to.

It will be recalled, as shown in FIG. 4, that the arcuate section 1Θ7 of lever 17XL is snapped over the crosswire 43χ of lower rack 37, causing the crosswire 43χ of the rack 37 to seat into the opening 109 of the arcuate section 107 between the wires 41χ and 412 of the rack 37. In addition, the lower lever ¹⁷ 1L ( ^as well as the upper level 17χα) includes a

handle 105 and a body 106 which includes the arcuate section 107 at the other end. The arcuate section 107 includes the opening 109, protuberance 111 adjacent to the opening 109 and the detent 113 adjacent to the protuberance 111.

As shown in FIG. 7, the components 107, 111 and 113 of the body 106 are split into two sections or portions, with arcuate section 107 being comprised of portions 107 and 107B such that protuberance 111 is split into portions 111A and Ills each containing a detent 113 (FIG. 4) located at the rear of the portions 111A and Ills _* In this manner, the ejector releases pin 128, which extends through the ribs 121, 122 and 123 of the lower glide 21, is seated into the detent 113 (FIG. 4) at the rear of the protuberance portions 111A a d lllg of FIG. 7.

The glide 21 is attached to the L-shaped bracket 133 (shown in phantom in FIG. 7) which is in turn.fastened to the metal plate 23 (see FIG. 5).

Note, as shown in FIG. 7, that the rib 121 of the glide 21 has a bottom portion 183 cut from the lower left to upper right at about a 45 degree angle and that the portion 183 is connected to a shoulder 184 which protrudes outwardly to the right. In a similar manner, the rib 123 of the glide 21 has a bottom portion 185 cut away from lower right to upper left at about a 45 degree angle and the portion 185 is connected to a shoulder 186 which protrudes outwardly to the left.

The bottom portion 183 and 185 of the glide 21 respectively rest between the wires 41χ and 412 of the rack 37. As a result, the card cassette 15χ (FIG. 2), which includes the upper glide 19 (FIG. 2) and the lower glide 21 (FIGS. 2 and 7), is mounted in the channel between the wires 41χ and 412 (of each of the racks 35 and 37 of FIG. 3) and is slideable into and out of the card cage 13 (FIG. 3). Note that the

distance between the ends of the shoulders 184 and 186 of the glide 21 is less than the 0.8 inch between the centers of the wires 41χ and 412 of the channel for the card cassette 15χ. Similar dimensions prevail for the other card cassettes 152 • • • 15 ^~ ~ shown in FIG. 1. As a consequence, the remaining cassettes 152 • • . 15jj of FIG. 1 can be similarly slideably mounted in associated channels between pairs of the remaining wires 412 . . . 41χχ of each of the racks 35 and 37 (FIG. 3).

The insertion, retention and extraction of the card cassette 15χ (FIG. 2) from the card cage 13 (FIG. 3) will now be discussed by again referring to FIGS. 1-7.

INSERTION

It will be recalled that the handles 105 of the levers 17χy and 17χL of FIG. 4 are adhered to magnetic surfaces (not shown) of the cabinet 11 (FIG. 1) after the levers 17χg and 17χL have been manually rotated in the directions of the respective arrows 115u and 115^ around the associated wires 43χ of the respective racks 35 and 37 into substantially horizontal positions. With the levers 17χg and 17 L in substantially horizontal positions, the protuberances 111 (FIG. 4) are also in horizontal positions. Thus, as the card cassette 15χ (FIG. 2) is being pushed horizontally into its associated channel between the wires 41χ and 412 of each of the racks 35 and 37 of the card cage 13 of FIG. 3, the ejector release pins 127 and 128 (FIGS. 4 and 5) of the respective glides 19 and 21 are also moving horizontally. These moving pins 127 and 128 strike the protuberance portions 111A ^an< ^ HIB' ^as shown in FIGS. 4 and 7, causing the levers 17χu and 17χL to be rotated in the directions of the respective arrows 187u and 187^ (FIG. 4), and the pins 127 and 128 then

engage the respective detents 113 of the levers 17χα and 17χL as they pass over the levers 17χg and 17χχ

The handles 105 of the levers 17χu and 17χL (FIGS. 4 and 7) are then simultaneously rotated by an operator in the respective directions indicated by the arrows 187g and 187χ This causes the card cassette 15χ (FIG. 2) to move from right to left, as indicated in FIG. 4. As the handles 105 are being simultaneously rotated, the portions 111 and Ills (FIG. 7) of the protuberance 111 (FIG. 4) of each of the levers 17χg and 17XL respectively pass through the gaps between the ribs 121 and 122 and the ribs 122 and 123 of each of the glides 19 and 21. This causes the levers 17χu and 17χL to start rotating toward the closed position.

When the levers 17χu and 17χL of FIG. 4 have been rotated such that the centers of the pins 127 and 128 are vertically aligned with the centers of the wires 43χ, of the racks 35 and 37, the levers 17χg and 17χL have reached a center position 189. At this center position 189 of the levers 17χg and 17χι,, there is a maximum interference or resistance to any further rotation of these levers in the directions indicated by the arrows 187u and 187χ This center position 189 of the levers 17χu and 17χχ. is also the point where the connectors 147 (FIG. 5) on the card cassette 15χ (FIG. 2) have just about made contact with associated mating connectors (not shown) on the back frame 39 of the card cage 13 of FIG. 3.

As the operator simultaneously rotates the levers 17χrj and 17χχ. further in the directions of the arrows 187u and 187^,- he pins 127 and 128 move further to the left to an over center / \ (delta) position 191 (as shown in FIG. 4), causing a mechanical advantage pressure to be applied to the connectors 147 (FIG. 5). As a result, the three connectors 147 at the rear of the card cassette 15χ

(FIG. 5) seat into associated shrouds (not shown) of the associated mating connectors (not shown) on the back frame 39 (FIG. 3) to engage those associated mating connectors. Thus, at the over center \ position 191 of the pins 127 and 128, the connectors 47 (FIG. 5) have fully engaged their associated mating connectors on the back frame 39 of the card cage 13 (FIG. 3).

RETENTION

The card cassette 15χ is retained in its associated channel between the wires 41χ and 412 of each of the racks 35 and 37 and with its connectors 147 (FIG. 5) fully engaged with their respective mating connectors 147 (not shown) on the back frame 39 of the card cage 13 (FIG. 3) by a locking condition which tends to keep the ejector release pins 127 and 128 at the over center / \ position 191 (FIG. 4).

To remove the card cassette 15χ, the handles 105 of the levers 17χu and 17χ∑, must be moved in the directions of the respective arrows 115u and 115L past the center position 189. It is the above-stated maximum interference or resistance to the rotation of the levers 17χu and 17χ£. from the over center /\ position 191 through or past the center position 189 (in the directions of the arrows 115τj and 115^) that creates this locking condition, which locking condition keeps the pins 127 and 128 at the over center / \ position 191 and hence keeps the connectors 147 (FIG. 5) fully engaged with their associated mating connectors (not shown) on the back frame 39 (FIG. 3).

EXTRACTION

To extract or eject the card cassette 15χ (FIG. 2) from its above-described channel in the card cage 13 (FIG. 3), the handles 105 of the levers 17χrj

and 17χι, (FIG. 4) are simultaneously forced by an operator to move in the respective directions indicated by the arrows 115g and llS,. This causes the levers 17χu and 17XL to respectively pull the ejector release pins 127 and 128 (see FIG. 1) of the glides 19 and 21 (FIG. 5), respectively, horizontally from left to right, as shown in FIG. 4. Thus, the horizontal movement of the pins 127 and 128 causes the card cassette 15χ to also move horizontally from left to right. The rotational movements of the levers 17χu and 17χL causes the protuberances 111 of the levers 17χu and 17χι, to pull the pins 127 and 128 from the center position 189 past the over center /\ position 191 to disengage the connectors 147 (FIG. 5) from their associated mating connectors (not shown) on the back frame 39 of the card cage 13 (FIG. 3). As mentioned before, the maximum interference or opposition to the rotation of the levers 17χg and 17χ . to disengage the connectors 147 from their associated mating connectors (not shown) in the back frame 39 (FIG. 3) occurs at the center position 189 of the levers 17χu and 17χι,. Typically, it could require an ejection force of 36 kilograms (80 pounds) to disengage the 96 pin DIN connectors 149 from the back frame 39. After the levers 17χu and 17χχ, pass the center position 189, the connectors 147 have been disengaged from the back frame 39. At this point of rotation of the levers 17χu and 17χχ, the operator can either physically grasp the card cassette 15χ and remove it from the card cage 13 or he can continue to rotate the levers 17χrj and 17χ . until they are in substantially horizontal positions. With the levers 17χjj and 17χL in substantially horizontal positions, the card cassette 15χ can be easily removed from the card cage 15χ by the operator. In either event, when the card cassette 15χ is removed from the card cage 13, the ejector levers 17χrj and 17χL remain with the

card cage 13 with their associated arcuate sections 107 snapped over the respective crosswires 43, of the racks 35 and 37 (via the openings 109).

An important feature of this invention is that it utilizes a mechanical advantage to insert or extract a card cassette 15χ (FIG. 2) into or from the card cage 13 (FIG. 3).

As shown in FIG. 4, there is a ratio of almost 5:1 between the distance from the center of the opening 109 to the extreme end of the handle 105 of an associated one of either of the levers 17χu and 17χL and the distance between the center of the opening 109 and the center of the detent 113 of that lever. This ratio provides a mechanical advantage that enables an operator to readily move the handles 105 of the levers 17χu and 17χι, past the center position 189 in either inserting or extracting a desired card cassette 15χ from the card cage 13 (FIG. 3). In addition, the opposition presented to the card cassette 15χ in moving past this center position 189 prevents the card cassette 15χ from coming out of the card cage 13 by itself. For example, if the card cassette 15χ were to try to fall out of the card cage 13 by itself during the shipment of the cabinet 11, the resistance or opposition that the card cassette 15χ would encounter in going from the over center / \ position 191 past the center position 189 would keep it locked in the card cage 13 at its over center / \ position 191. An external force would be required to remove the cassette 15χ from the card cage 13.

Another important feature of this invention is that only a minimum amount of force or stress is placed on the processor board or printed circuit card 29 (FIG. 5) in the insertion, retention or extraction of a card cassette, such as the card cassette 15χ, into, in or from the card cage 13 (FIG. 3). This minimizes the chance of cracking or otherwise damaging

the processor board 29, particularly during the extraction of the card cassette 15χ from the card cage 13 when a relatively large amount of force is required to disengage the connectors 147 (FIG. 5) from their associated mating connectors (not shown) on the back frame 39 of the card cage 13 (FIG. 3). Such minimization of stress on the processor board 29 (FIG. 5) is due to the fact that the processor board 29 is mounted to the card cassette 15χ (FIG. 5) by way of the metal plate (FIG. 5) and the associated upper and lower card ejector levers 17χø and 17x1, are mounted to the card cage 13 (FIG. 3) and not to the processor board 29 or to the card cassette 15χ. As a consequence any strain or force applied to the card cassette 15χ is transferred from the pins 127 and 128 in the glides 19 and 21 of the card cassette 15χ to the connectors 147 (FIG. 5) via the metal plate 23 (FIG. 5) rather than via the processor board 29.

The invention thus provides an apparatus for respectively controlling the insertion, retention and ejection (or extraction) of card cassettes into, in and from a cassette or card cage of a housing with a minimum amount of stress or force being applied to the printed circuit card or processor board of each of the card cassettes.