DK149729B - CONNECTOR - Google Patents

Description

in 149729

The invention relates to a connector, e.g. for printed circuit boards, having a first rigid insulating contact holder relative to a second rigid insulating contact holder, e.g. a circuit board, with conductive terminal grooves, can be displaced in parallel in the insertion and withdrawal direction, the first contact holder having elastic contact members, one end of which is fixed relative to this first contact holder, and which contact members having a hinge joint and two generally rectilinear parts 10 which is inclined relative to each other, and whose junction point constitutes the active zone of the contact member, by which the contact member can touch the conductive terminal grooves with an appropriate tension force when the two holders are properly connected together, and the first holder also has a control mechanism. which can be operated by an operator and is adapted to actuate the elastic contact means for opening and closing, the control mechanism having at least one slidable slide for controlling the parts of the contact member across the sliding direction of the slider.

20 It has long been sought to develop connectors with contact means which "open" immediately before or during the insertion of a circuit board, as well as immediately before or during the extraction of such a card. This avoids that part of the card, and especially the card's terminal groove, is "swept" away from the active zone of the contact means, and the forces to be used in the take-in and withdrawal are reduced to almost nothing. Furthermore, wear on the protective coatings is avoided, both on the contact means on the first contact holder and on the conductive terminal grooves on the second contact holder, the circuit board. When the card is in its working position, the said control canism "closes" the contact means again.

From US Patent No. 3,475,717 such a connector for printed circuit is known. When a circuit board is inserted into this connector, a slider or plate is displaced so that this plate presses against the end of one or more elastic contact means. In this way, the contact zone's active zone is pressed against the leading terminal groove of the circuit board. When this connector is to be opened, the plate is retracted so that the plate no longer presses the end of the contact leg. Thereby, however, no actual clearance is created between the contact leg 5 and the circuit board's leading terminal groove. Such clearance is subject to a spring action in the contact leg so that the contact leg tilts away from the circuit board. Such a spring can change its spring force (material fatigue) during use. There is thus a risk that after some use 10 a part of the contact legs will hang up the circuit board and cause this wear marks on withdrawal and withdrawal.

The object of the invention is therefore to provide an electrical connector, especially for printed circuit boards with such controlled contacts, that a circuit board can be safely inserted into the connector without causing wear and tear between the circuit board's terminal slots and the connector's contact members, and where the connector contact means may be affected. , that they make contact with the circuit board's leading terminal slot.

This object is achieved in accordance with the invention in that each contact member identifies a slidable end attached to the slider and that the slider for closure moves this end against the hinge joint of the contact member, which is generally in the same plane as the slidable end.

This contact member can be compared to a deformable three edge, the two sides of which are the two rectilinear portions of the contact member and the third side of the triangle is fictitious, namely the line of connection between the hinge joint and the displaceable joint. to the slider attached end. The lengths of the first two sides 50 are almost constant, while the length of the third fictitious side depends on the position of the slider. In the opening position, the slider occupies a position where the fictional side of the triangle assumes its maximum length. The geometric height of the triangle on the fictional side is thus the least possible. In other words, the angular tip of the triangle opposite the fictional side (i.e., the active zone of the contact member) is relatively close to the slider, corresponding to the active zone being pulled away from the circuit board. If you now slide the slider in the closing direction, press: this on the sliding end of the contact member, fixed in the slider. Thereby, the fictional side of the triangle is shortened and the geometric height of the fictional side is increased, corresponding to the active zone of the contact member being pushed up against the circuit board and coming into contact with the corresponding terminal groove. During the last part of the slider movement, the active zone of the contact member will flatten out because it is pressed against the terminal groove. This gives you better control of the height of the triangle and thus the contact pressure regardless of any material fatigue. As a result, it will be possible to completely remove the contact pressure during the removal of the circuit board, while at the same time the contact pressure can be restored after the introduction of the circuit board.

The sliding end of the contact member can be held in the slider in a recess by a bias in the hinge joint of the contact member. With this design, it will be possible to separate the sliders and contact members in case one wishes to clean and repair the connector. Another option is to solder the sliding end into a corresponding hole in the slider. Thus, a secure and permanent anchorage of the contact member is provided in the slide. Furthermore, the slider may be provided with a projection which holds the sliding end of the contact member.

25

The slider and the contact member may advantageously be designed so that the slider grabs the active zone of the contact member by a displacement in the closing direction and during the last part of the closing movement the active zone draws a small piece. This provides a cleansing effect, dragging the contact member a short distance along the conductor terminal slot of the circuit board, thereby sweeping away impurities which could cause poor contact. The self-cleaning effect can be achieved, inter alia, in that the two oblique parts of the contact member are connected to a spiral winding, which at one time constitutes the active zone and an attack surface for the said part of the slider formed by the supporting member that the supporting member can grip in the spiral winding and pull it during the last part of the closing movement.

In order to obtain the best possible abutment surface, the support means should be approximately perpendicular to the inclined parts of the contact member, which are terminated by the slidable end fixed in the slider.

According to the invention, the contact means between its fixed end (opposite the slidable, fixed in the slider) and the hinge joint may include a flexible curvature consisting of two successive curves of opposite curvature (i.e., the curvature has a sinusoidal arc) followed by a part which is enclosed in an auxiliary holder which can be displaced parallel to the slider and which is driven against a stop collar in the direction of the slider opening movement. The connector may here be arranged such that during the closing movement of the slider, the auxiliary holder first engages the stop collar until the active zone of the contact member touches the terminal groove. During the closing phase of the closing movement, the slider pushes the auxiliary holder with it, while keeping the position of the two inclined parts of the contact member unchanged 20 with respect to the slider. In this embodiment of the invention a controlled cleaning of the contact surfaces is achieved.

According to the invention, the hinge joint can be designed as a spiral winding. During the latter part of the closing movement, where the contact zone of the contact member is pressed up against the terminal groove of the circuit board, the active zone will sweep over a small portion of the terminal groove and the rectilinear part of the contact member lying between the active zone and the coil winding. , will be shortened during the last part of the closure, corresponding to a lil-2q le piece of this rectilinear portion being wound up in the winding, thereby obtaining a larger diameter. This embodiment also provides a controlled cleaning of the contact surfaces.

Finally, the hinge link may be formed of two oppositely directed arcs which may similarly accommodate a small portion of the adjacent rectilinear portion of the contact member. Also with this design a careful and controlled cleaning of the contact surfaces is achieved.

149729 5

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows the connector according to the invention with a printed circuit board circuit; FIG. 2 is a section through the connector along line II-II of FIG. 1, FIG. 3 shows the one shown in FIG. 1 shows part III in perspective view, with some parts being omitted, fig. 4 of the upper part of the left slider in FIG.

1 on a large scale, but shown here in its second outer position, I® fig. 5 is a cross-section through the main parts of FIG. 3 in two different positions, the upper half of FIG. 5 shows a closed contact member and the lower half one open contact member; FIG. 6a and 6b are a schematic cross-section through a connector close to the stone shown in FIG. 5 in the two different working positions, fig. 7, 8 and 9 show three different designs of the connector 25 shown in perspective, partially cut away; 10a and 10b are schematic sections through the embodiment of FIG. 7 in two different positions, 50 fig. 11a and 11b are schematic sections through a fifth embodiment of a connector in two different working positions; 12a, 12b and 12c are schematic sections through a sixth embodiment of a connector in three different working positions. 13a and 13b are schematic sections through a seventh embodiment of a connector in two different working positions.

The connector is shown in its entirety in FIG. 1 and 2 and has a rectangular frame 1 shown only at the top of FIG. 1 on the side 5 opposite the insertion side of the printed circuit boards, such as the card 2. The insertion and withdrawal direction of the card is shown with the double arrow A in FIG. 1. In addition to the insertion side, the frame has three sides, at least one of which has a connector provided with elastic contact means 3 (see Figs. 3 and 5), which are 10 perpendicular to the relevant frame side. According to the embodiment shown in FIG. 1, the two sides of the frame parallel to the direction A are provided with two connectors 6.7 on one side and 8.9 on the other side. The contact means 3 are arranged to be able to touch the conductive connection grooves 15 5 which are perpendicular to the nearest edge of the card 2, with the active zone 4, when the card occupies the working position shown in FIG. 1 and at the top of FIG. 5th

Each connector includes two sliders 10 and 11 which are made of insulating material and which are symmetrical about a plane midway through the frame, which plane is marked P-P in FIG.

2 and 5. These sliders each have two dovetail-shaped pins or zinc pins 12 (shown only in Figure 3), which can slide into similarly-shaped openings or grooves 13 provided 25 in a U-shaped housing or rod 14 which is made of an insulating material. This housing is designed in one piece for each of the connectors 6 to 9. Due to the shape of the dovetail-shaped pin or Sinktap 12 and the groove 13, the slides 10,11 are retained by themselves in the housing 14 and cannot fall out 30. The contact means 3 have no influence on the holding of the slides 10 and 11.

On the top and bottom of each housing 14 is provided a longitudinal groove 15 into which a slider 35 or 17, preferably metal, can be slid. As shown in FIG. 1, each slider is common to the connectors 6.7 and 8.9 respectively located on the same side of frame 1. Likewise, as shown in FIG. 3 and 5, the slides 10, 11, 149729 7 are adjacent to their sinking pin 12 in direct contact with the slider 16 or 17, which furthermore touches the bottom of the groove 15. Each slider 16 and 17 is partly provided for each of the connectors 6 to 9. with two guide grooves 18 arranged to displace the slides 5, 10,11, and partly two guide grooves 19 arranged to displace side pieces 20 surrounding each of the connectors 6 to 9. As shown in FIG. 4, the grooves 18 and 19 comprise a first portion 18a and 19a that is inclined with respect to the longitudinal direction of the slider 16 and 17 and bends away from the interior of the frame 1, and a second portion 18b and 19 parallel to the direction of the slider. In each groove there is inserted a shaft 21 with a roller 22, which shaft 21 is attached to a slider 10 or 11. Also in the groove 19 there is inserted a shaft 23, which is provided with a roller 24, and which is fixed to the side piece 20, which may be of metal 15. Each side 20 is provided with a shaft 23 on each side of the median plane P. The parts are composed so that - depending on the position of the sliders 16 or 17 - (as shown in Fig. 1) all the shafts 21 will be in the inclined portion of the groove 18 18a in that slider, and all the shafts 23 will be 20 in the parallel portion 19b of the groove 19 in the same slider, or (as shown in Fig. 4) all the shafts will be in the parallel portion 18b of the groove 18 while all the shafts 23 are in the slant portion 19a of the groove 19. The side pieces 20 cooperate with the control device in such a way that they can be moved in a direction perpendicular to the longitudinal direction of the sliders 16 and 17 and parallel to the median plane P. Furthermore, each slider 16 and 17 is provided with an operating means which in FIG. 1 is shown as a control arm 25 which enables the operator to move it longitudinally, to be able to move the slides 10 and 11 and the side pieces 30 20 transversely, as will be explained in detail below.

The sliders 16 and 17 of the connectors 6,7 and 8,9 are held and covered at the top and bottom by a pair of metal plates 26 (not shown in Fig. 1, but shown in Fig. 5, and in Fig. 3 a little of the 35 ). Between the side edges of the two plates 26 is a gap the height of which is greater than the height or thickness of the printed circuit board 2. On each edge supports screw plates 149729 δ 27 which have corresponding side edges (or edges) so that they control: the card 2 , when inserted into said space.

In FIG. 1,3 and 5, there is also shown an insulating plate 28 called the "motherboard" on which the end 5 3a of the contact means 3 protrudes.

According to the embodiment shown in FIG. 3 and 5, the contact members 3 are made of resilient metal wire having a generally circular cross section.

10

With a rectilinear piece 3b adjacent to the end 3a, each member 3 is attached to the housing 14 as it passes transversely and extends along the flat bottom 29a of a recess 29 having a rectangular profile formed in the slides 10 and 15 11. The bottoms 29a of the slides 10 and 11, respectively, are arranged parallel to the plane P passing through the frame 1. The rectilinear piece 3b is arranged so that the bottom 29a can slide against the piece 3b by displacing the slides. Each member 3 has a recess 29 oriented perpendicular to the longitudinal direction of the sliders 16 and the width of the recesses should be only slightly greater than the thickness of the contact members 3, at least in the vicinity of the active zone 4. Each recess 29 is limited. of the side surfaces of two teeth 30 in the rectangular profile, as shown in FIG. 3. Between the teeth 30 of the slides 10 and 11 25 there is a sufficiently large gap for it to receive the edge 2 of the card. The rectilinear piece 3b ends with a loop or coil 3c, after which the member 3 leaves the bottom 29a of the recess 29 with an inclined portion 3d forming a blunt angle with the rectilinear piece 3b. The inclined portion 30b is followed by a rounded portion constituting the active zone 4, and then by an inclined portion 3e which is nearly symmetrical with the inclined portion 3d relative to a line perpendicular to the bottom 29a. This oblique section 3e is finally terminated by a short section 3f almost perpendicular to the bottom 29a. The end portion 3f is secured in a blind hole 31 at the bottom 29a.

In particular, due to the presence of the loop 3c, the contact member 3 has some elasticity such that its terminating end 3f is constantly pressed against the bottom of the hole 31, which is caused by the displacement applied by the slides 10,11. Depending on whether the slider 10 or 11 assumes its open position (bottom of Fig. 5) or its closed position (top 5 of Fig. 5), the active zone 4 is withdrawn or protrudes relative to the teeth 30 due to it. greater or lesser distance between the loop 3c (fixed) and the endpoint 3f (movable with the slider 10 or 11).

10 As shown in FIG. 3, each side 20 has a cut-out 32 towards the center of the frame 1. The outer edge 32a of each cutout 32 together with its upper 32b and lower 32c edge is obliquely cut or rounded to the side where the card 2 is to be inserted to facilitate insertion and centering of the card 2. At each pair of side pieces 20 disposed in the same vertical plane (the plane perpendicular to the direction A in Fig. 1), the distance between the outer edges 32a is greater or less than the size of the card depending on the position the side pieces 20 are forced by the sliders 16,17.

20

Hereby a connector is obtained which functions as follows. It is first assumed that the sliders 16,17 occupy the position shown in FIG. 1, wherein the shafts 21 attached to the slides 10,11 are at the bottom of the inclined portion 18a 25 of the groove 18 and the shafts 23 attached to the lateral core 20 are at the bottom of the parallel portion 19b of the groove 19. It is also assumed that, contrary to what is shown in FIG. 1, no card is inserted into the connector. The shafts 21 and thus the slides 10, 11 are in the position furthest away from the interior of the frame 1 as shown in the upper half of FIG. 5. In other words, the distance between the loop 3c and the end portion 3f is the minimum for all the contact members 3. The active zone is thus furthest from the bottom 29a of the recess 29 and protrudes from the teeth of the sliders 35 30. For reasons mentioned in the the following, it is detrimental to the shape and shape of the contact means 3 and to insert the groove 5 into the connector 2 into the connector. But at the same time, the side pieces 14 * 729 or 20 are in the position furthest to the interior of the frame. The distance between the outer edges 32a of the cutouts 32 considered two and two is less than the width of the card 2, which makes it impossible for the operator to introduce it by default.

5

By displacing the operating arms 25 as shown by the arrows in FIG. 1 or by actuation of other analogously acting means, the operator may then first move the sliders 16,17 upwards in FIG.

1 to the position shown in FIG. 4. During the first part of this movement, the shafts 23 pass through the parallel legs 19b of the guide groove 19 in such a way that the side pieces 20 remain motionless. At the same time, shafts 21 pass through the inclined portion 18a of guide rails 18, which displaces slides 10 and 11 toward the interior of the frame. Thus, the sliders 10,11 come from the position at the top of FIG. 5 to the position shown at the bottom of the same figure, in which the distance between the loop 3c and the end 3f is maximum, whereby the active zone 4 is retracted and disappears into the recesses 29. The contact means 3 have been fully opened. In the second half of said movement 20, the shafts 21 pass through the parallel portion 18b of the guide grooves 18 in such a way that the slides 10,11 remain motionless. At the same time, the shafts 23 pass through the inclined portion 19a of the guide grooves 19, whereby the side pieces 20 occupy the position where they are furthest away from the center of the frame, ie.

25 is closest to the plate 28. The operator can then insert the card 2, which is facilitated by the obliquely cut or rounded edges 32b, c on the notches 32 of the side pieces 20 (see Fig. 3). When the card occupies the working position shown in FIG. 1, the operator moves the control arms 25 in the opposite direction of the arrows in FIG. 1. It results in the same movements, but in the opposite order and direction, which is described below. In other words, the side pieces 20 first approach each other so that the card is locked. Therefore, the card has notches 39 (Fig. 1) which the side pieces 20 can penetrate. Then, the slides 10,11 are displaced away from the center of the frame so that the contact members 20 are closed (as shown in the upper half of Fig. 5). Thus, these contact members are forced to close

IX

t48729 with a tension force predetermined by their geometric and elastic characteristics and by the displacement of the slides 10,11.

Of course, in order to later remove the card, at least 5 must be made the first part of the maneuvers just described: opening of the contacts 3 and an unlocking by separating or spreading the side pieces 20.

The self-cleaning effect obtained according to the invention is illustrated in Figs. 6a and 6b. FIG. 6a shows the contact member 3 in the open position and FIG. 6b in the closed position.

If one imagines a triangle whose two sides are constituted by the two legs 3b and 3e, one can see that the displacement of the slider 15 10 from the position in fig. 6a to the position of FIG. 6b will shorten the length of the third side (called the fictitious side in the introduction) from the value "L" to the value "1" and at the same time increase the height, namely the height that is lowered on the third side from the value h to the value H. the height 20 first causes contact between the active zone 4 with the groove or conductor path of the corresponding connection (in the position shown in dashed line in Fig. 6b), then a slight displacement of this active one 4 relative to the track mentioned above, accompanied by an increase in contact pressure (until the position fully drawn in FIG.

6b. This explains the fact that, under the pressure applied to it from the inclined portion 3d, the loop or winding 3c approaches the shown portion of the housing 14 by changing from the open position (FIG. 6a) to the closed position (FIG.

30 6b) while increasing the diameter of the winding. Thus, the inclined portion 3d is shortened, allowing the inclined portion 3e terminating with the active zone to be moved without deforming in practice from the position shown punctured to that fully drawn in FIG. 6b, i.e. that the active zone 35 cleans the conductive track on the card 2 over the length d separating the two outer positions. In order to facilitate the deformation of the winding, in contrast to the embodiment of FIG. 3 and 5 that it does not support slider 10.

Pig. 7, 8 and 9 show three different embodiments of the invention. The reference steps used in FIG. 7 to 59 are the same for parts 3, 3a, 3b, 3c, 3d, 3e, 3f and 4 of FIG. 3, 5, 6a and 6b, only increased by 40, 50 and 60 respectively.

Unlike the various embodiments shown in the foregoing, the contact means 43, 53 and 63 do not have any loop or coil winding, such as 3c, which may be inconvenient if the electrical current through the contact members has a very high frequency, but the contact member is provided with what is hereinafter referred to as "flexible curvature" 43c, 53c and 63c, 15 each composed of at least two successive curves of opposite curvature. Flexible curves of this kind are "hinge joints" according to the terminology used in the description introduction, and have the advantage, among other things, of being smaller than the loop or coil winding. Next to the flexible 20 curves 43c, 53c and 63c, the housing 14 may be provided with a groove or recess 14a perpendicular to the grooves 13 to prevent these flexible curves from touching the housing, which would impede their free movement and movement. deformation. For the same reason, the slider 10 and the contact member 25 are arranged together so that the bottom 29a of the recess 29 is kept separate from the nearest leg 43d, 53d, 63d of the contact member.

According to the embodiment shown in FIG. 7, the contact member 43 is formed of a circular wire (one or more twisted) whose outer end 43f is inserted into a blind hole 31 formed in the slide in the same manner as shown in FIG. 3, 5, 6a and 6b. According to a variant not shown for the case that it is not planned to be able to separate and assemble the contact member 43, the end 43f can be secured by welding using the holes 31 which are first metallized or by inserting the end 43f in the slider 10 bottom.

149729 13

In the embodiment of FIG. 8, the contact member 53 is also formed of a round wire, but its end is fixed in a different way. For this purpose, it has at its free end two tight-fitting loops or turns 55 which form two lateral 5 projections which can surround a rib 56 forming a projection into the recess 29 perpendicular to its bottom 29a. As in the previous cases, the bias to which the contact member is subjected seeks to press the tight-fitting loops 55 toward the bottom 29a of the recess 29.

10 In the embodiment shown in FIG. 9, the contact member 63 is formed of a metal band. At the fastened end, this contact member has a side notch 64a in the side, and a rib 65 analogous to the rib 56 in FIG. 8 can go into the notch. Preferably, in the metal band constituting the contact member 63, there are a plurality of longitudinal continuous slots 66 adjacent to the active zone 64 and in any of the inclined portions 63d and 63e so as to secure as many contact zones with the conductive groove of the card as there is. slats are delimited by these slots 66.

20

As in the case of FIG. 6a and 6b, the contact means 43,53 or 63 in FIG. 7,8 and 9 are subjected to a bias so that its fixed end is always pressurized against the bottom 29a of the recess 29 of the slide 10. This, on the one hand, prevents this end from slipping out from the place in which it is folded. , and, on the other hand, the mounting or replacement of the contact means in the connector is facilitated. Despite the fact that the loop 3c of FIG. 3,5,6a and 6b are missing in the connectors shown in FIG. 7,8 and 9, self-cleaning 30 is assured, as explained with reference to FIGS. 10a and 10b. It is only to simplify the description that the only references to FIG. 7 is transferred to FIG. 10a and 10b. Moving the slider 10 from the position of FIG. 10a to that of FIG. 10b, 35 is first induced as already explained in connection with FIG. 6a and 6b raise the active zone 44 until it touches the conductive groove of the card 149729 14 (as shown by the dotted line in Fig. 10b), after which the contact member 43 is substantially deformed to the flexible curvature 43c, allowing for the leg 43e, terminated by the active zone 44, to be displaced in parallel, thus ensuring the self-cleaning of the contact surface.

By means of fig. 11a and 11b and partly FIG. 12a, 12b and 12c, particular advantageous embodiments will now be described in connection with slider 10 or 11 performing a displacement 10 in the direction of closing the contact means. During this offset, the slider grabs part of the contact member and pulls it with it during the last part of the offset.

FIG. 11a and 11b show such a configuration which is used 15 as an example of a connector which is otherwise identical to that of FIG. 7.10a and 10b. In accordance with this embodiment, the two oblique legs 43d and 43e of the contact member 43 are connected by a loop or coil winding 46 which simultaneously forms the active zone 44 and an attack or abutment surface 20 of a support member or protuberance 47 on the slider 10 so as to able to grasp this loop or coil winding 46 and pull it. The support member 47 is preferably inclined and forms an angle of the order of 70 ° with the base 29a or approx. 90 ° with the leg 43e. The positions of FIG. 11a and 11b correspond respectively to those of FIG. 10a and 10b. During the shutter direction (from the position of Fig. 11a to the position of Fig. 11b), the support member 47 automatically pulls the loop 46, whose active zone 44 cleans the terminal grooves of the card 2 under increasing pressure. The loop 46, whose advantage is to ensure a double contact with the connecting groove, can also be replaced by another deformation or a completely different system suitable for cooperating with the support member 47. The inclination of this last increases the pressure of the winding 46 against the connecting groove. .

35

FIG. 12a, 12b and 12c show a variation of the preceding figures. The same reference numbers only increased by the analogous parts of FIG. 10a and 10b. In addition to the flexible curvature 73c, the contact member 73 of FIG. 12a, 12b and 12 have a flexible curvature 73h, the characteristic of which is to be disposed between the housing 14 and an insulating holder 75 which, at displacement 3, is enlarged parallel to the path of the slider 10. Between the curvature 73h and the leg 73d, the contact member 73 has a portion 73e attached to the insulating holder 75. The latter is influenced by the tensioning force of the curvature 73h and is held by the external tensioning force against a stop collar 76 during the opening movement of the slider 10. The insulating member 10 holder 75 is disposed in the path of the slider 10 so that it is guided by the slider during the closing movement.

FIG. 12 shows the connector in its open position, whereby the active zone 74 is consequently removed from the card 2. If the slider 10 is moved from left to right, the holder 75 first remains in the same position pressed against the stop collar 76, and that portion of the means 73 comprising legs 73d and 73e initiate its deformation in the same manner as described in connection with FIGS. 10a and 10b until the position of FIG. 12b, where the active zone 74 begins to touch the two connecting grooves of the card under pressure and begins the self-cleaning, after which the slider 10 touches the holder 75. By continuing the movement of the slider 10, the position in fig. 12c. Between FIG. 12b and 2c 12c, the legs 73d and 73e undergo no deformation, so that the active zone 74 abuts the conductive track with the same tensile force. At the same time, the insulating holder 75 is moved a little to the right of the conductor 10 under slight compression of the flexible curvature 73h, and the active zone 74 is displaced 30 the same piece, which ensures self-cleaning.

As described above, the hinge joint is formed as a loop or coil 3c or flexible curves 43c, 53c, 6 or 73c. Another embodiment of this part constituting the hinge is shown in FIG. 13a and 13b. In these figures, the same reference numerals as in FIG. 6a and 6b, only increased by 80. In this case, the leg 83 closest to the housing 14 is provided with a greater length united with some originally built curvature (see Fig. 13a) so that it has a greater flexibility than the leg 83e closest to it. fixed end 83f, which leg 83e is initially rectilinear. When the slider 10 is displaced from the position 5 of FIG. 13a to the position of FIG. 13b, the active zone 84. first comes into contact with the card terminal groove and then slides against the groove while increasing the curvature of the leg 83d, and thus the beginning point of the curvature 83c forms a hinge joint.

As mentioned in the preamble and in connection with the description with reference to the accompanying drawings, the connector is adapted to connect a printed circuit board 2's connecting conductors with elastic contact means such as 3,43,53,63,73,83 arranged on a frame. , which is attached to the housing 14 and arranged 15 to control this card. Thus, frame 1 and card 2 are only examples of two rigid insulating holders and can be replaced by other rigid insulating holders, one of which carries the elastic contact members and the other carries the connecting grooves and the holders are designed to fit 20 in parallel with the insertion and withdrawal direction. One can also design cylindrical or rectangular connectors that can be assembled. As such connectors are well known, the use of contact means of the invention on such connectors will not pose any difficulty to those skilled in the art.

Thus, it is not necessary to show connectors of this kind equipped with the contact means according to the invention in the drawing.

The invention is not limited to the embodiments described and illustrated. Thus, e.g. possible to have a different number of connectors than two on at least one of the parallel sides of the frame of FIG. In addition, ordinary connectors or connectors according to the invention can be mounted on the side of the frame which is opposite the insertion side, ie. the top 35 of Fig. 1.

Finally, the distance between the edges / protrusions of the two plates 26 may have a height not only greater than the thickness of the card 2 (as explained above), but which will also be sufficiently large to allow the passage of the contact means 3 if the must be replaced.

According to most of the embodiments described 5 above, the active zone 4 (contact zone) is the only one for each contact member 3. However, it will be possible to multiply such contact zones in one of the following ways: of a wire whose curvature is such that when placed, that curvature will tend to be directed beyond a certain length, thereby creating a linear contact, - or by a wire made of waves if peaks 15 will each touch the groove 5, - or in such a configuration of these shackles that, after mounting, a linear contact is established between two wave peaks 20 Ρθ '- or by a spiral wire whose cross-section is generally constant and may be round , rectangular, square or square (in a broader sense), etc., 25 - or by using two or more threads which may be intertwined or non-intertwined and generally of the same cross-section throughout, - or by one of the solutions, there we are st in FIG. 9 and 11a, 11b.

35

Claims (6)

149729 Patent Claims. 1. Connector, e.g. for printed circuit boards, having a first rigid insulating contact holder (1), relative to which a second rigid insulating contact holder, e.g. a circuit board (2), with conductive terminal grooves (5), can be displaced in parallel in the insertion and pull-out direction (A), wherein the first contact holder (1) has elastic contact means (3). one end (3b) of which is fixed with respect to this first contact holder (1), and which contact means have a hinge joint (3c) and two generally rectilinear parts (3d, 3e) 10 which are inclined relative to each other, and if junction constitutes the active zone (4) of the contact means, whereby the contact member can contact the conductive terminal grooves (5) with an appropriate tension force when the two holders (1,2) are properly connected together and the first holder (1) furthermore has a control mechanism operable (25) by an operator and adapted to actuate the elastic contact means (3) for opening and closing, said control mechanism having at least one slidable slide (10,11) for controlling said contact member portions transverse to the sliding direction of the slider, characterized in that each contact member comprises a slider partially attached to the slider (3f) and that the slider for closure moves this end against the hinge joint (3c) of the contact member, which is substantially in the same plane as it tries dull end. Connector according to claim 1, characterized in that the sliding end of the contact means (3f, 43f, 53f, 63f, 73f, 83f) can be retained by means of a bias in the hinge joint (3c, 43c, 53c, 63c, 73, 83c) in a mounting arrangement (31, 56, 65) provided in the slider (10, 11) for this purpose. 149729 Connector according to claim 1 or 2, characterized in that the slider (10,11) and the contact member (43) are individually designed (47,46) such that when the slider (10,11) performs a displacement to close 5, the slider engages a part (47) during the displacement part of the contact member (46) and pulls it during the last part of the displacement (Figs. 11a and 11b). Connector according to claim 3, characterized in that the two oblique parts (43a, 43b) of each contact member are connected via a coil winding (46) which at one time constitutes the active zone (44) and an attack surface for it as a supporting member. designed said part of the slide (10,11) so that the support means (47) can actuate the coil winding (46) at its surface 15 and pull it. Connector according to claim 4, characterized in that the supporting member (47) of the slider (10,11) is approximately perpendicular to the inclined part (43e) of the contact member which is terminated by the sliding end (43f). The connector of claims 1 and 2 for printed circuit boards, wherein the largest contact holder (1) consists of a frame for controlling a printed circuit board constituting the second contact holder (2), characterized in that the contact means (73) between its fixed end (73a, b, which is opposite to the displaceable end Uf), and the hinge link (73c) comprises a flexible curvature (73h) formed by two successive curves of opposite curvature, followed by a portion (73g), 30 secured in an auxiliary holder (75) which can be displaced parallel to the slide (10,11) and driven against a stop collar (76) in the direction of the opening movement of the flider (10,11), which connector is thus arranged to assist the auxiliary holder. (75) during the closure movement of the slider first abuts the stop collar 35 (76) until the active zone (74) of the contact member touches the terminal groove (5), after which the slider (10,11) pushes the auxiliary holder (75) with it while the position of Contact-