NL8303621A - IGNITION DEVICE. - Google Patents

Description

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Contact making device.

The invention relates to a contact touching device according to the preamble of claim 1.

Contacting devices of this kind are known (KROGER "Prüfmittel zur elekten Prüfung von Leiter-5 platten für Uhren", Jahrbuch der Deutschen Gesellschaft für Chronometrie, Band 30, 1979, pp. 269-276). Such contacting devices serve for testing conductor plates or like electronic construction parts of the electronic industry in order to test the newly manufactured, relevant conductor plates or the like parts quickly or simply before or after their equipment, and to measure whether they are free from errors. the test specimen is electrically scanned simultaneously at several or generally very many locations simultaneously by means of contact pins of the contact making device.

The survey sites are often located very close to one another, the closer together as the conductors are narrower and the conductor distances of the sample are smaller. Such contacting devices primarily serve to test the conductor tracks of not yet equipped conductor plates for short circuit between adjacent conductor tracks or other faults of the conductor plates, for example interruptions or the like before they are equipped with further electronic elements. In many cases, therefore, such contacting devices can be used not only for the above research purposes, but also for measuring purposes, possibly of already equipped conductor plates or other electronic construction parts, for example for resistance measurements and the like.

Heretofore, such contact terminals have been provided with very many multi-prong contact pins, with straight contact rods loaded by individual springs bearing axially displaceable bearings in the individual springs. However, such contact pins are expensive in manufacture. Also, the centerline distances of neighboring contact pins cannot be made as small as is desired in many cases. In the prior art rigid sleeve resilient contact pins, the centerline spacing between adjacent contact pins cannot be made less than about 0.8 mm. Even smaller center-line distances down to about 0.4 mm in such contacting devices have hitherto only been achieved by means of the tactile electrode test heads described in the aforementioned publication on pages 275, 276, wherein the spring contact pins are provided with a jacket in which there is a spring-loaded piston, which is provided with a thread-like extension threaded in flexible tube. These test heads are also very expensive and their dimensions are very limited.

The object of the invention is to provide a contact-making device of the type mentioned in the preamble of claim 1, wherein the contact pins have a constructionally simpler and cost-effective / cost-effective design and wherein also particularly low centerline distances from the probe end regions of neighboring contact pins.

According to the invention this object is achieved with a contact making device according to claim 1. Because the contact pins are elastic metal wires, they can be manufactured relatively cheaply and simply. These contact pins can thus be one-piece construction elements. The metal wire may preferably be a solid metal wire. In special cases it is also possible to use metal wires as contact pins. According to the invention, a considerable saving of the manufacturing costs of the contact making device is achieved. Particularly small center-line distances from neighboring pin-end areas of the contact pins can also be achieved, for example when placing the contact pins in the grid points of a grid field with very small grid distances, which are also less than 0.4 mm, for example 0.2 to 0.3 mm or even smaller under certain circumstances can be 40. This also provides new uses for this test specimen contact making device, especially with particularly narrow and particularly closely spaced conductor tracks. Due to the fact that the contact pins are secured against rotation, an unintentional contact of the contact pins can be prevented at small distances between neighboring contact pins and the suitability of the contact making device to be ensured even under unfavorable conditions, since there is no confusion and mutual damage between the bent areas of the the contact pins may develop. For this purpose, the bent-out region of the contact pin can preferably be flat and these flat-bent regions of the contact pins of the individual contact pin row can extend in the plane of the respective contact pin row or run at an angle thereto and through the securing does not distort or does not disturb the surfaces provided therefrom.

The contact pins also allow relatively large axial contact forces of preferably 10 to 100 grams per contact pin or more, which is beneficial or even often necessary for a reliable, resistive contact.

The invention also makes it possible to design the carriers in such a way that the contact pins can be mounted particularly simply and quickly and with them inexpensively and can also be exchanged cheaply and easily again.

For this purpose it can preferably be ensured that the support contains two rigid, preferably mutually parallel bore plates. These may advantageously be spaced apart from one another - allowing insertion of the contact pins through the interspace between these plates into their bores, with the outer sides of the two plates facing away from each other facing the front and rear. of the carrier 35.

Other embodiments of the carriers are also possible, for example the carriers can have a single passage for each mountable contact pin into which the contact pin is inserted, this passage slitting in the region of the deflection of the contact pin. 2 f -4- can be designed to provide anti-rotation of the contact pin and after insertion of the contact pin in this passage it is closed by a plug provided with an axial bore through which the respective straight end area of the stylus penetrates.

It is particularly advantageous if the bent-out bent regions of the contact pin serving for the axial self-suspension of the contact pin lie in a geometric plane also comprising the longitudinal axes of the contact and terminal end areas of the contact pin.

Since all contact pins can effectively be designed identically, thus despite the bends, particularly small center-to-center distances between adjacent contact pins and thus very small grating distances of the grating field can be provided in case the contact pins are arranged in a grating field. It is admittedly also possible not to arrange the contact pins according to a grid field, but depending on the situation in other arrangements.

If it is not necessary to observe particularly small grating distances, it can also be ensured that the deflection or deflections of the separate contact pin lie flat, but are designed three-dimensionally, for instance in order to increase the axial suspension properties of the contact pins. change.

Examples of embodiments of the invention are shown in the drawing. In the drawing: Fig. 1 shows a multiple broken-away top view of a favorable embodiment of the contact-making device according to the invention, Fig. 2 shows a side view of the contact-making device in Fig. 1, viewed in the direction of the arrow A, interrupted 35 and partly cut Fig. 3 shows a side view of the contacting device from Fig. 1, seen in the direction of the arrow B, interrupted, Fig. 4 shows a side view of a part of a further embodiment of the contacting device according to the 8303621 Invention, fig. 5 a. sectional view along the line VV in fig. 4, fig. 6 sectional view along the line VI-VX in fig. 4, fig. 7 a side view of a further embodiment of the contact making device according to the invention, shown in broken position, fig. 8 a side view of the contact making device of fig. 7, viewed in the direction of the arrow C, fig. 9 is a top view of a part of the contact making device of fig. 7, 10-10 sections of parts of further embodiments of the contact making device according to the invention, and FIG. 17 is a front view of a further embodiment of the contact making device according to the invention.

The contact making device 10 shown in Figs. 1 to 3 comprises a window-shaped support 14, which consists of two mutually parallel, flat and rectangular bore plates 11, 12, as well as two side bore plates 11, 12 spaced apart from each other. stand plates 13. Both bore plates 11, 12 may preferably be made of very rigid, electrically insulating plastic material with good sliding property, for example plastic material, which is marketed by the company DU PONT, USA under the name 25 "Delrin "which is an acetal resin of polymerized formaldehyde (Polyoxymethylene). Each of the two bore plates 11, 12 is provided with a plurality of bores 15, 16 arranged according to the grid points of a predetermined grid field, each bore 15 of the upper bore plate 11 aligned with a bore 16 of the lower bore plate 12. The side 24 of the bore plate 12 forms a first flat side of the support 14, which can also be referred to as the front.

In this exemplary embodiment, the side 23 of the carrier 14 then forms a rear side.

The grid points of the grid field, which determine the longitudinal axes of the bores, can correspond to the intersections of a geometric grid network with square grid fields. Depending on the field of application of the contact making device 10, it is not necessary to drill into the bore plates 11 and 12 at all the grid points of the grid sheet bores 15, 16. The centerline distance between adjacent bores 15 and 16 respectively of the bore plate 11, 5 and 12, respectively, can preferably be very small, in particular less than 0.8 mm, preferably 0.2 to 0.4 mm and optionally even smaller. According to the invention, the high drilling density required for this (this is the number of bores in a bore plate and therefore the number of contact pins per surface unit) can therefore be very high, so that this contact making device for testing and possibly measuring electronic construction parts, in particular conductor plates with very small conductor distances and very narrow conductors 15 is suitable.

The bores 15 of the upper bore plate 11 are very narrow long bores for the further elucidation described below • against rotation of the contact pins 17 inserted in bore pairs 15, 16 of the bore plates 11, 12, while the bores 16 in the lower bore plate 12 have circular cross sections. In accordance with the achievable small bore center distances in the separate bore plate between adjacent bores, the bores can have very small cross sections, for example in the case of circular bore holes 16 (bottom bore plate 12) with a diameter of 0.1 to 0.3 mm. Optionally, the centerline distances can also be smaller or larger. A particular advantage of the invention is that very small bore sizes 30 and center-to-center distances between adjacent bores of the bore plate 11 and 12, respectively, are possible in that the contact pins 17 are also designed as only a single spring wire.

Furthermore, the two bores 15 and 16, which are mutually aligned, and which serve to receive a single contact pin 17, are respectively designated the upper bore plate 11 and the lower bore plate 12 as a bore pair.

The support 14 may preferably have a very large number of 40 such bore pairs, for example 100 to 83 0 3 6 2 100-500 bore pairs or optionally even more or in particular cases also less. In this connection, it should be noted that not all bore pairs need to be occupied with contact pins 17. In practice, cases occur where it is expedient to occupy all bore pairs with contact pins 17, while in other cases only a portion of the total number of bore pairs is occupied.

The contact pins 17 are mutually identical and project with their end regions 20, 21 beyond the mutually parallel outer side 23, 24 of the carrier 14 and formed by the bore plates 11 and 12 and consist of resilient, high-quality metal wire, for example of copper beryllium, copper zirconium, spring steel, new silver, curable precious metal alloys or similar high-quality metallic materials, which have good electrical conductivity and resilient properties.

The one-piece contact pins 17 can preferably consist of solid metal wire, which if desired still. can be galvanically, chemically or otherwise * coated in whole or locally with non-corroding or a particularly good contacting and / or wear-resistant metal such as gold, iridium, rhodium, palladium, nickel or silver or the like, in particular especially at the touch points 19 and at the connection end area 20.

The contact pins 17 are preferably solid, as this provides great stiffness, strength and high contact pressures, and is moreover considerably cheaper than providing hollow wires. However, in special cases hollow wires can also be provided if for some reason this is desired.

The separate contact pin 17 has two straight, mutually aligned end regions 20, 21 between which it exhibits a single deflection 22 in the form of a flat, elongated "U", the length of which is considerably greater than its depth. top 40 straight end region 20 of contact pin 17 is flattened 8303621 -δέη has an approximately rectangular cross section, which with the small cross section of the longitudinal bore 15 of this upper region 20 of the upper plate 11 substantially corresponds to this difference, 5 is slightly smaller in cross-section than that of the longitudinal bore 15, so that this terminal area 20 serving for the electrical connection of the contact pin 17 and the plain bearing play required for the insertion of the contact pin for inserting it into this longitudinal bore 15 is straight-lined in the longitudinal bore 15 and, through its elongated cross-section, fills this connecting end area with sliding bearing play, against rai is fitted securely. The other straight end region 21 of the contact pin 17 forms the pin end region of this pin and has a conical touch point 19 - also called contact point - at its free end and is in the round bore 16 of the bore plate 12 provided for receiving it. it protrudes before coming into contact with specimens, axially straight 20 lined with sliding bearing clearance, so that this probing end area can axially shift through the axial forces exerted by the specimens at the probe point 19 in the bore 16, with a resilient deformation of the bulge 22 which provides the required restoring force 25 for returning the stud end region 21 to its rest position. For example, an electrical connection socket of an electrical conductor can be inserted on the part of the terminal end area 20 projecting beyond the outside 23 of the carrier 14, or other electrical connection options are present, for instance under multiple soldering and welding of an electrical conductor, for instance a lead wire.

In this connection, it is pointed out that in general, in each case, only a number of the contact pins 17 35 at their terminal areas 20 need to be connected to further conducting electrical conductors, namely only the contact pins, which in a given test specimen are intended for predetermined locations of the test specimen electrically to test for its correct operation, respectively 40- an error-free, for example, 83 0 3 6 2 1 S Λ • -9- for testing the conductivity of a conductor track or the like part .

The bent-out region 22 of the contact pin 17 is longer than the straight stud end region 22 and the straight terminal end region 20, and its length approximately corresponds to the sum of the lengths of said end regions 20, 21. The deflection 22 extends on all sides freely over the entire small distance between the two bore plates 11, 12 from bore 15 to bore 16 of the respective bore pair, so that the contact pin 17 is hereby retained in its axial rest position, and nevertheless by pressing the touch point 19 through a bending of its deflection 22 can be deformed resiliently axially by displacing the stud end region 21 axially in an upward direction as indicated by the double arrow E. The connecting end region 20 cannot be displaced in the axial direction, since this is prevented by the deflection 22.

Preferably, the length of the deflection 22 in the case of a relaxed contact pin 17 not yet inserted in the carrier 14 may be slightly greater than the small distance between the two bore plates 11 and 12, so that the deflection 25 can elas in the case of the contact pin 17 inserted in the carrier 14. is slightly axially compressed and biased with it, thereby achieving a particularly good accurate, axially play-free attachment of the contact pin 17 in its rest position in the carrier 14.

The individual contact pin 17 can be mounted in a simple manner by inserting this pin in a suitable manner in bending the inner space 25 of the carrier 14 with its probe end area 21 and its connecting end area 22 in the two bores 15 receiving these areas 35. and 16. The mounting of the contact pins 17 is expediently carried out in such a way that the deflections 22 of all contact pins 17 are placed parallel to each other as shown in figure 3 for two contact pins 17. Expressed otherwise, the distance between the contact pins 17 inserted in neighboring bore pairs 15, 16 of a bore pair row is approximately the same at any height along the entire length of the contact pins 17, so that optimum protection against accidental contact with one another contacting of the contact pins 17 is achieved, even when the distances between the contact pins 17 are very small.

Nevertheless, under certain circumstances, the danger of contacting neighboring contact pins 17 could occur if only one of the two neighboring contact pins 17, having their deflections 22 in the same geometrical plane, compressed axially resiliently when testing a test specimen but not the others, care can be taken to provide the deflections 22 of the contact pins 17 at least in the areas in which the danger of contacting neighboring contact pins 17 under adverse conditions could possibly arise. electrically insulating coatings or the surfaces of the deflected regions 22 of the contact pins 17 of the individual contact pin row at an angle to the plane defined by the pin end areas 21 of this contact pin row.

As. As a result of the deflection 22. of the contact pin 17, the tactile tip 19 thereof can spring axially in the direction of the double arrow E because the deflection 22 is elastically bent. When testing a test specimen, the displacement distance of the tactile tip 19 in relation to the length of the deflected area 22 is very small, so that the deflected area deflects only slightly laterally at most 30 when the specimen end area is displaced axially then corresponds to the position of the deflection in the rest position of the contact pin 17. Therefore, even at very high bore densities, in at least many cases an electrically insulating coating of the bent areas 22 of the contact pins 17 can be omitted.

In the contact making device 10 'shown in FIGS. 4, 5 and 6, an anti-rotation of the contact pins 17, again consisting of elastic solid metal wires, is achieved by 40 parallel longitudinal slots 26 of rectangular cross-section in the bore 8303621. Plates 11 and 12 retracted positively, flat electrically insulating slats 27. Namely, the contact pins 17 have deflections 22 located in planes parallel to the slats 27, which consist in the manner shown in FIG. towards curved half waves. The axial suspension property of the contact pins can hereby be further improved. The bent-out region 22 of the contact pin 17 formed by the two semi-corrugated deflections extends again from the bore plate 11 to the bore plate 12 and is preferably prestressed in the inserted state of the contact pin 17. A straight connecting end region 20 adheres to this bent-out region 22 - a straight connecting end region 20 at the top and a likewise straight tip end region 21 at the bottom 15, which penetrate through the two mutually aligned bores 15, 16 of the respective bore pair a certain sliding bearing clearance and protruding beyond these bores 15, 16. In this exemplary embodiment, the contact pin 17 can have a continuous round cross-section and can therefore be bent from a round wire.

The touch point 19 is conically focused. The bores 15 and 16 of the bore plates 11 and 12, respectively, also have a round cross section.

When a tactile tip 19 is displaced in the axial direction by a test specimen during an elastic bending of the bent-out bearing area 22, both half-wave bends of the double-sided bent-out flat area 22 of the contact pin 17 are moved to both sides 30 in the plane of the bending slightly more elastically bent, but only to a small extent, so that again, even at very small contact pin distances, there is no danger of contacting neighboring contact pins, or in the case of very small distances this danger could nevertheless the relevant areas of the contact pin 17 as already described can be provided with electrically insulating coatings.

The slats 27 can for instance consist of very thin electrically insulating plates of glass, plastic or the like, which have a sufficient inherent stiffness, but which need not be very high.

The deflection of the contact pin 17 to both sides in the bending plane (fig. 4) has the advantage over the bending to a single side, as is the case with the contact pin 17 of fig. 3, for example. bending of the contact pin 17 with an axial inward movement of its touch point for a test specimen is slightly smaller.

The deflected region 22 of the contact pin 17 can also have more than two half waves, so that it can also obtain a one-flat, serpentine wound shape.

Figures 7, 8 and 9 show a further embodiment of the contact making device 10 ”according to the invention. In this case, the support 14 is formed in one piece and the upper bore plate 11 thereof is also provided with mutually parallel longitudinal slots 30 with a rectangular cross-section, which, however, do not serve for receiving slats, but on the side at the front. the bottom of which the bores 15 of the upper bore plate 11 open for carrying the touch-end areas 21 of the contact pin 17. Each contact pin 17 has a bent part 31 in the region of the respective slot 30, whereby the pin is secured formally in the slot 30 against twisting. This bent part 31, together with a second bent part 32, provides the deflection 22 of the contact pin 17 which serves for an axial springing of the pin end region 21. The upper bent part 31 of the contact pin 30 17 also effects the form-locking of the contact pin 17. against twisting. This deflection 22 furthermore ensures the attachment of the contact pin 17 in the two bore plates 11, 12 comprising support 14, such that the pin is not fully axially displaceable, but only axially resiliently compressed while bending the deflection. can become. The bent-out area 22 can already be efficiently under pretension already in the rest position of the contact pin 17 inserted in the carrier 14.

In this exemplary embodiment, each of the contact pins 17 again consists of solid metallic round wire and the width of the grooves 30 is slightly larger than the diameter of these round wires.

Numerous modified embodiments are possible according to the invention. For example, instead of securing the axial rest position of the contact pin 17 in the carrier 14 by the deflection 22, care can be taken that, as shown in Fig. 10, the bent-out area 22 extends over only a partial area of the small intermediate space between the two bore plates 11, 12 of the carrier 14 and that the axial rest position of the contact pin 17 is ensured in other ways, for example by short, flattened widenings 33, 34 of the contact pin 17, which are directly on the mouths facing each other. the bores 15, 16 of the respective bore pair of the bore plates 11, 12 come to lie as shown in an example in Fig. 10, the bent-out area 22 of the contact pin 17 as shown having a rectangular shape of small width and depth and first begins at a distance from the flattening 33, 34. The shown shape of the deflection 22 has, inter alia, the advantage that the axial suspension of the contact pin 17 does not lead to a lateral deflection of the deflection 22, but through the two longitudinal legs of the deflection 22, as indicated by dashed lines. accomplished by bringing the two longitudinal legs closer together. This reliably avoids any danger of contacting adjacent contact pins in the row by this embodiment of the bent-out region 22. Securing against twisting of the contact pin is here achieved in part by the widening 33 located close to the connecting end region 22 in that this widening engages in a groove 35 of the bore plate 15 in a form-fitting manner against twisting.

In the contact devices shown, the contact pins have very cost-effective constructions, since they consist of bent, resilient, preferably solid metal wires. The mounting of these contact pins 40 is also very simple, since they come from the inside of the 3. * T “c ~ -. λ. -14- carrier 14 can be inserted into the bores 15, 16, so that damaged contact pins 17 can easily be exchanged for new contact pins 17. The carrier 14 can be rigid per se and the two bore plates 15, 16 can not are detachably or releasably attached to the spacing sidewalls 13. It is also possible to connect the two bore plates in the manner of platinum by means of spacer tubes through which connecting threaded pins are passed. The support 14 can optionally be formed in one piece, for example by casting and subsequent machining.

It is also possible to assemble the contact making device from several or many contact making elements, each of which forms a contact making device in itself, and several of these contact making devices are then mutually connected to form a larger contact making device. The individual contact elements can then have relatively small dimensions, for example a base surface of 20 x 20 mm or 40 x 40 mm.

This facilitates the mounting and exchange of the contact pins and makes the production of larger contact-making devices cheaper because they can be assembled from desired case-by-case from prefabricated smaller contact-making devices, which can be referred to as contact-making elements. Such a contact sensing element can also be used, for example, as a probe electrode test head and thus replace the probe electrode test head described in the Jahrbuch der Deutschen 30 Gesellschaft für Chronometrie on page 273 et seq. And is then considerably more cost-effective with the same function.

Instead of, as has been proposed in the exemplary embodiments according to fig. 1-9, the securing of the axial rest position of the contact pin 17 in the carrier 14 by means of a single bent-out region 22, it can also be ensured, for example, that this securing of the axial the rest position can be achieved by two longitudinally spaced curved regions spaced apart, for example, by two regions corresponding to the region 22 of the contact pin 17 of FIG. 10 the one region abutting the upper bore 15 of the bore plate 11 and the other region abutting the lower bore 16 of the bore plate 12 instead of the planes 33 and 34 shown in FIG. 10. In the exemplary embodiments shown in FIG. For the sake of clarity, the distances between neighboring contact pins 17 are shown relatively large for the sake of clarity. However, it is readily apparent that they can be made smaller than suggested. In the exemplary embodiment of the contact making device according to Fig. 7-9, this is further explained with reference to a numerical example. With this contact making device 10 ", the round wire of the contact pin 17 may, for example, have a diameter of 0.10 mm. The length of the contact pin 17 may, for example, be approximately 30 mm. The width of the slot 30 and the diameter of the bores 15, 16 may be approximately 0.11 mm and the length of the bent parts 31, 32 may be 0.18 mm, for example, the center line distance 20 between the pin end areas 21 in the row of adjacent contact pins 17 and therefore the center line distance of neighboring bores 16, In the respective row, respectively, approximately 0.30 mm and the center-line distance between adjacent contact pin rows can then possibly be even smaller, for instance 0.2 mm.

As has already been explained, it may often also be effective to ensure, instead of the flat deflections of the contact pins of a contact pin row in the plane (row plane) defined by the probe end areas thereof, the flat deflections to achieve particularly small center-to-center distances between neighboring pin end areas, respectively to reduce or eliminate the danger of contacting adjacent contact pin deflections at an angle to the row plane, the surfaces of the deflections being parallel to each other or with neighboring contact pins angles of inclination with the row plane are placed. It is also possible, if the deflections 22, as for instance shown in Fig. 10, are only spread over a part of. \ - * A λ χ; . ii -iff - 'w * ^ m 1 -16- extend the small height between the bore plates, stagger the deflections of neighboring contact pins in the longitudinal direction of the contact pin so that in principle they do not can come into contact with each other.

The deflections 22 for the axial self-suspension of the contact pins 17 are intended to impart to these contact pins 17 the characteristic of bending springs, the deflections 22 being advantageously located between the bore plates 11, 12 in the exemplary embodiments.

While in FIGS. 1-10 the contact pins 17 are drawn with double lines, they are simplified as single lines in the remaining FIGS. 11-17. Also in these exemplary embodiments, the elastic metal wire of each contact pin 17 with sliding bearing play is axially guided in the two bores 15, 16 receiving these pin bores 11, 12 of the respective carrier 14, as well as in the previous embodiments. so that each contact 20 pin 17 can be pushed into the bores 15, 16 receiving this pin for mounting and into the bore 16 located close to its tactile point 19 when it comes into contact with a test specimen through the bore 16 axially are displaced under elastic bending 25 of the extended area 22 of the contact pin, which in these embodiments is also located in the area of the contact pin 17 between the two bore plates 11, 12 in each case. In Figs. 11-17, the bores 15, 16, which carry the contact pins 17, are exaggerated for the sake of clarity. In reality, they receive the contact pins 17 with an axial sliding bearing clearance, therefore with little lateral clearance.

In the exemplary embodiment of FIG. 11, the deflection 22, which effects the axial self-tensioning of the metal wire of the contact pin 17, is formed by a circular winding of this metal wire, which extends over 360 °. This winding 22 is designed as the winding of a coil spring, but in this embodiment not circular, but elongated; Stretches. Instead of one turn, several turns may also be formed, but normally it is amply sufficient and advantageous to form only a single turn on the contact pin. This winding 22 is again located between the two bore plates 11, 12, but at a distance therefrom. In order to secure the axial position of the connecting end 20 of this contact pin 17 against axial displacement, in this exemplary embodiment it is protruding beyond the rear side 23 of the bore plate 10 ii of the connecting end region 20 of the contact pin 17 by pressing a tool. its circular circular cross-sectional metal wire flattened to a flat disk 40, the diameter of which is greater than the diameter of the bore 15 is of the bore plate 11. This flat disk 40 is in a rear longitudinal slot 26 'of the bore plate 11 inserted with a slight lateral play to secure the contact pin 17 against twisting and is secured against movement in the direction of the longitudinal axis of the bore 15 by means of a plug plate 41, 20 of which the back 23 of the carrier 14 forms. with a plug contact 42 embedded herein pushes the disc 40 from above so that this disc 40 is against presses the bottom of the slot 25 * of the bore plate 11. The slot 26 'can optionally also be inserted in the plug plate 40. This resilient contact pin 17 can be mounted in such a way that it has a terminal area 20 which has not yet been flattened, so that the diameter of the other metal wire of the contact pin 17 is therefore still the same as in the previous embodiments from the space between the two bore plates 11 and 12 are inserted into the bores 15 and 16 of the respective bore pair. After this, the connection end region 20 is pressed by means of a tool ^ to the disc 40. If the bending elasticity of this contact pin 17 is sufficient, it can also be mounted in such a way that its connection end region is already flattened into the disc before assembly. 40, after which the metal wire is first pushed into the bore 15 from above with the feeler-40 point 19 2: ~ *>?

«V

-18- and is pulled through the bore 15 when the winding is tightened, after which this metal wire is then pulled through the bore 16 and after relief the winding 22 then forms as shown.

In the embodiments according to fig. 11-11 described heretofore, the two bores 15, 16 of each bore pair serving to receive a contact pin 17 are mutually aligned. However, it is also possible to place these two bores 15 and 16 of a bore XO pair in a mutually staggered arrangement, which has the advantage, among other things, that this already achieves the locking of the contact pin 17 against twisting and therefore no other drilling measures against twisting are required. Figures 12-17 show some embodiments, wherein the. for each axial self-suspension of the contact pins by bending, the deflections 22 each on all sides are freely located in the interspace between two bore plates 11 and 12.

In the exemplary embodiment 20 shown in Fig. 12, the bores 15 and 16 of each pair of boreholes of the two bore plates 11 and 12 are mutually offset laterally with their longitudinal axes and mutually parallel, with each individual bore 15 and 16, respectively, as in the preceding exemplary embodiments. .1 25 to 11 run perpendicular to the flat front 23 'and rear 24 of the bore plates 11 and 12, respectively. These sides 23 'and 24 are parallel to each other.

The deflection 22 of the contact pin 17, as in FIG. 11, is formed by a winding of a metal wire of the contact pin 17. In this exemplary embodiment, the connection area 20 of the metal wire of the contact pin 17 is a separate part. metallic head 40 'fixed, for example welded. The heads 40 'of the contact pins 17 are again pressed against the bore plate 11 by means of a contact plate 41 which contacts these contacts, which contact pin can be provided for each contact pin 17 and the plug contacts of which are electrically insulated from each other, so that the terminal areas 20 cannot again experience axial shift 40. This connector plate 41 is in fig. 12, 13 and λ - ^ -; * “-19- 16 indicated only with dashed lines. This plug plate 41 is fixedly connected to the plate 11. Optionally, it can also be ensured that this plug plate is elastically pressed by means of spring means against the heads 40 and 40 '(Fig. 12) of the contact pins 17 and is guided straight in parallel with this pressing device.

The contacts 42 of the plate 41 can optionally also be other contacts such as plugs, for example bushes X0 and / or busbars or similar elements, so that this plate 41 can generally be referred to as a contact plate.

In the exemplary embodiment shown in Fig. 13, in order to secure against rotation of the contact tips 17, the straight holes 15 located in the bore plate 11 located close to the terminal end region 20 are no longer perpendicular to the plane of the foregoing examples. bore plate 11, but placed obliquely on this plane, while the bores 16 located in the other bore plate 12 are further drilled perpendicular to the plane of this bore plate 12. Each contact pin 17 consists of a metal wire of round cross-section, which, however, as in the exemplary embodiment according to Fig. 1, is provided for the same purpose as there, with a flattened head 40, which forms the connecting end area 20 and through a contact plate 41 against the bore plate 11 is pressed. The springy metal wire of the contact pin 17 is elastically bent in the region between the two bore plates 11 and 12 as a bent-out part 22, which again masks its axial self-suspension in the manner of a bending spring. This bent-out portion 22 is formed even when the elastic metal wire of the contact pin 17 is straight before insertion into the bore plates 11, 12 due to the unaligned arrangement of the two axial contact pins plain bearing play carrying bores 15 and 16 in connection with the shown flattened widening 34, which corresponds to the widening 34 of the 40 pin 17 of fig. 10. Just in case, because of this the 8303321

* V

If the pre-tension required for this contact pin to become too great its friction in the bore 16, it can be ensured that this contact pin 17 in the relaxed state already has approximately the bent-out semi-wave region 22, so that the friction in the bore 16 is minor. The bent-out parts 22 of the contact pins 17 are here open deflections, while in the exemplary embodiments according to Figs. 11 and 12 they can be referred to as closed deflections 12.

The exemplary embodiment shown in Fig. 14 substantially corresponds to that according to Fig. 13 with the difference that the bores 15 of this bore plate 11, which are inclined at an angle to the bore plate 11, are more staggered laterally to the bores 16 of the bore plate 12 and that the contact pin 17 does not have a semi-wave-shaped bend, but only an approximately ν'-shaped one. bending. The legs of the V enclose a large angle as shown. Also, the contact pin 17 does not have a widening 34. In this exemplary embodiment, the 3rd locking of the contact pin 17 against an axial displacement of its terminal end area 20 is achieved, as in Fig. 11, by a contact plate 41 in connection with the widened heads 40.

In this exemplary embodiment, the mutual distance between the two bore plates 11 and 12 is adjustable, while the relative position thereof is also adjustable in the direction of their surfaces. As a result, the bore plate 11 is provided on the outer edge with longitudinal slots 45, through which mounting bolts 46 pass, which serve for the 3rd fixing of this bore plate 11 to side plates 48 of the carrier 14. After loosening the screw bolts 46, the bore plate 11 can be turned to the left or to the right and thereby adjust both the spring force of the contact pins 17 and the projection of their tactile end regions 21 beyond the bore plate 12. Also, the protruding region of the stud ends 21 beyond the bore plate 11 can be made independent of the set spring force in that bore plate 12 is secured to the side plates 48 by means of fastening 40 screw bolts 47, which pass through the longitudinal slots 49 in at xi ·. ·; .? Vertical strips 50 attached to the bore plate 12. After loosening the fixing screw bolt 47, the bore plate 12 can be vertically adjusted up and down relative to the bore plate 11, while by tightening these fastening screw bolt 47 the bore plate 12 can be brought into the desired position relative to the bore plate 11. The insertion of the contact pin 17 can take place from the rear 23 of the bore plate 11 in both bores 15 and 16, as is readily apparent.

In the embodiment shown in Fig. 15, the contact pins 17 again have V-shaped bends, in this embodiment the two bores 15, 16 of the bore-15 pair each receiving a contact pin 17 'in the two bore plates 11 and 12 in opposite directions. are directed obliquely to the bore plates 11 and 12. The angles of inclination of these bores 15 and 16 with respect to the surfaces of the respective bore plates 11 and 12 can be the same size or of mutually different sizes. As in the exemplary embodiment according to Fig. 11, a locking of the contact pins 17 against axial displacement of their connecting end regions 20 is provided.

In the exemplary embodiments described heretofore, the bores 15, 16 associated with neighboring contact pins 17 in the two bore plates have equally great mutual distances, so that the two bore plates 11, 12 each have identical bore patterns in these exemplary embodiments, which must be interpreted in such a manner. that in the bore patterns only the position of the bore outlets located on one side is important and not the possibly occurring inclination of the bores relative to the bore plate.

According to the invention, however, the possibility is also provided in a simple manner that the bore patterns of the two bore plates 11 and 12 need not be identical, but may deviate from each other both in geometry and in size. For example, FIG. 16 shows part of a contact making device 10, wherein the distances of the 40 adjacent bores 16 shown in the bore plate 12 are significantly smaller than the distances between neighboring bores 15 in the vicinity of the terminal end regions 20 of bore plate 11 located on the contact pins 17. As a result, the distances between the connecting end regions 20 can be increased, or the distances between the pin end regions 21 of the contact pins, which can be advantageous. Incidentally, the two bore plates 11 and 12 are similar to those according to Fig. 14, which also applies to the contact pins 17. It can also be ensured that one or some of the bore pairs present in the two bore plates 11 and 12 mutually correspond to one another. line. The contact pins 17 can have mutually different shapes.

Fig. 17 shows a simplified embodiment of such a contact making device 10, wherein the bore patterns of the two bore plates 11 and 12 are of different sizes. Only a square of bores 15, 16 is drawn on both bore plates 11 and 12. In reality, however, each bore plate contains numerous further bores within these two bore squares, which can also be arranged in a square, but also in a different configuration. The bore pattern of the bore plate 12 is a reduction of the bore pattern of the bore plate 11. Each contact pin 17 is fed into a bore 15 of the bore plate 11 and into a bore 16 of the bore plate 12.

As has been explained, the insertion of the contact pins 17 in the two bore plates 11, 12 can take place from the interspace between these two bore plates 11, 12, but in many cases this is also possible from the outside as with reference to the exemplary embodiments according to Figures 11 and 14. In the latter cases, the distances between the two bore plates 35 11 and 12 may be smaller than when the contact pins 17 are inserted into their bores 15, 16 from the interspace between these bore plates 11, 12.

When it has been discussed in the foregoing that the contact pins 17 were locked against twisting, it appears that it is usually permissible if locking against an 8303621 -23 twist is only such that the contact pins 17 cannot pivot too much. Small pivoting movements of the contact pins 17 are generally permissible. The lock against twisting therefore does not usually have to be a lock which would already prevent the slightest pivoting movements of the contact pins, although this can also be ensured if this is desired.

All exemplary embodiments show lockings against twisting of the contact pins 17, which can be referred to as form-fitting mechanical rotary locks. This is particularly advantageous, partly because they normally allow contact pins. can be exchanged for damage or other reasons. Also, because of the large numbers of the most fine bores, very expensive bore plates 11, 12 can be provided with other contact pin patterns, since not all bores 15, 16 need to be occupied by contact pins 17. In many cases, however, it is also possible to use force-locking rotary locks for example, to coat the rear side of the bore plate 11 after insertion and lifting of the contact pins 17 with a thin adhesive layer, to which the connecting end areas 20 of the contact pins protrude. The contact pins are then • not detachably held and thereby secured against turning. As mentioned, however, it is advantageous to arrange the contact pins 17 releasably.

With regard to the embodiment of FIG.

It is further noted that in many cases it is particularly effective if the centers of the two plates 11, 12 do not lie vertically one above the other, but the longitudinal center axes thereof are laterally offset from each other in order to avoid this, that in the center of the plates are bores 15, 16 serving for receiving the contact pins, which are mutually aligned. However, if such aligned bores 15, 16 are provided, then the respective contact pins 40 can be made, for example, as in the exemplary embodiment shown in FIGS. 1-3.

The bore plates 11, 12 can advantageously be formed of electrically insulating, form-retaining material such as glass, plastic or ceramic material.

Porcelain or ceramic oxide material with a high electrical resistance value is particularly suitable as ceramic material. Glass and ceramic material. exhibit the advantage of a particularly high dimensional stability. Other form-stable materials are also eligible, such as aluminum, the surface of which is also electrically insulated in the bores 15, 16 by metallic oxidation. Other metals can also be used for the bore plates if their surfaces are sufficiently electrically insulated by insulating surfaces or otherwise. Mineral materials are also eligible for the bore plates 11 and 12. Preferably, use can be made of a mineral material which is marketed by the company Rosenthal, Selb (Bavaria) under the name "STENAN".

Since the bores in the bore plates have a very small diameter and must be drilled very precisely, in addition to mechanical drilling, laser drilling, electron beam drilling, ultrasonic drilling and the like drilling operations are suitable for manufacturing these.

In the exemplary embodiments shown, the bore plates 11, 12 and, where present, also the contact plate 41 are placed parallel to each other and flat, which is already expedient because the contact pins 17 can thus be made mutually identical. However, it is also possible not to place the two bore plates 11 and 12 and possibly also the contact plate 41 parallel to one another if this is desired for some reason. In this case the contact pins can then be designed differently.

With regard to Fig. 13, it should also be noted that the separate contact pin 17 for its mounting first does not expediently have the widening 40 and is thus inserted from the interspace between the two bore-40 plates 11, 12 into the bores 15, 16. and then her terminal end region 20 is flattened to obtain the head 40. The widening of the contact pin 34 limits the axial downward movement of its probe end region 21.

5 - conclusions - m 8303621

Claims (47)

1. Contacting device for testing or measuring electronic test specimens, in particular conductor plates or the like, with a large number of electrically conductive and axially resilient, very thin contact pins, which are electrically insulated in bores of a rigid carrier and the axially resilient movable probe tips serving for contact with specimens protrude over a first side of the carrier, while the terminal tips of the contact pins remote from the probe tips serve for the electrical connection thereof, characterized in that the contact pin (17) is an elastic metal wire which, for an axial suspension of its touch point (19), has at least one bent-out area (22) that is resiliently flexible, such that this bent-out area (22) has the axial movability of the touch point (19). ) by elastically bending this bent-out area (22), and that the contact sti is secured against rotation in the carrier (14). 2. Contact-making device according to claim 1, characterized in that the bent-out area or the bent-out areas (22) of the contact pin (17) lie in a geometric plane, the longitudinal axes of the touch-end area (21) and of the connecting end area ( 20). Contact-making device according to claim 1 or 2, characterized in that the contact pins (17) formed by metal wires are of mutually identical design. Contact making device according to claim 2 or 3, 8303621 V -27- characterized in that the bent-out areas (22) of the contact pins of a straight contact pin row in the through-the-tip areas (21) and terminal areas (20) of the contact pin row lie flat and deflections of these contact pins formed at the same height are bent in the same direction. Contact-making device according to one of the preceding claims, characterized in that at least 10 a large number of contact pins (17) are placed on predetermined grid points of a geometric grid field, which grid points are arranged in straight, parallel rows, the distances between the grid points in the rows preferably 15 may correspond to the distances between adjacent rows. Contact-making device according to one of the preceding claims, characterized in that the tactile end region (21) and the connecting end region (20) of the contact pin (17) are straight and mutually aligned. Contact-making device according to one of the preceding claims, characterized in that the support (14) contains two rigid bore plates (11, 12), which are preferably placed parallel to one another. Contact-making device according to one of the preceding claims, characterized in that each contact pin (17) is guided in two spaced apart bores (15, 16) of the carrier (14), one (16) of which is close the probe end region (21) and the other (15) are close to the terminal end region (20), and that at least one deflected region (22) of the contact pin (17) is in the region between the two bores (15, 16). Contact-making device according to claim 8, characterized in that the contact pin (17) with sliding bearing clearance is placed in the two bores (15, 16) conducting hair. Contact-making device according to claim 8 or 9, characterized in that in the unloaded rest position of the contact pin (17) its bent-out area (22) for securing the axial rest position of the contact pin from bore (15) to bore ( 16) indicates whether a bent-out region of the contact pin starts at each of these two bores and, since the bent-out region (22) is preferably prestressed in the rest position of the contact pin. Contact-making device according to claim 8 or 9, characterized in that the connecting end area 15 (20) of the contact pin (1.7) is provided with a wide, metallic head (40), which is secured against an axial displacement between two plates ( 11), 41) of the support (14), preferably between a bore plate (11) and a contact plate (41). .20 Contact sensing region according to claim 11, characterized in that the widened head (40; 40 ') is a flat pressed part of the metal wire of the contact pin (17) or a separate metal part, which is attached to the metal wire of the contact pin. Contact-making device according to one of the preceding claims, characterized in that the contact-end areas (21) of the contact pins (17) projecting over the first side of the carrier run parallel to one another. Contact-making device according to any one of the preceding claims, characterized in that the contact pin (17) engages in a slot or slot-shaped recess (30) of the carrier (14) for securing against rotation with a bent-out area (22). 8303621 -4 * -29- Contact-making device according to one of Claims 1 to 13, characterized in that the contact pin engages a slot or slot-shaped recess (30; 26 ') of the carrier for locking against turning with a flattened part (33; 40'). 14). Contact-making device according to claim 14 or 15, characterized in that the slot (30) is formed on the inside of the bore plate, preferably on the bore plate (11) located close to the connecting end areas of the contact pins. Contact-making device according to any one of claims 7-13, characterized in that for securing the contact pins against rotation between the two bore plates (11, 12), mutually parallel blades (27) are provided, between which narrow slots are left open. surfaces from which the bent-out areas (22) of the respective contact pins extend for locking against rotation. Contact-making device according to one of Claims 1 to 13, characterized in that the support (14) comprises a bore plate (11) or the like plate, which is provided with longitudinal bores (15, for securing the contact pins (17) against rotation. Fig. 1-3) for form-fitting guiding of the contact pins (17) fed therein. 30 Contact-making device according to any one of claims 7-18, characterized in that the bores (15, 16) of the carrier carrying the contact pin (17) are mutually aligned. 35 Contact-making device according to one of Claims 7-18, characterized in that the two bores of the carrier (15, 16) carrying the contact pin (17) are not mutually aligned. 40 Contact-contacting device according to claim 20, because of the fact that the bores carrying the contact pin (15, 16) are arranged parallel to each other with their axes. Contact-making device according to claim 20, characterized in that the bores (15, 16) carrying the contact pin are disposed at an angle to one another. 10 Contact-making device according to one of Claims 20 to 22, characterized in that the longitudinal axis of the bore (16) located close to the probe end region (21) of the contact pin (17) is placed obliquely on the plane of the side located close to the probe end region (21). 24) 15 from the support (14). Contact-making device according to any one of claims 20-23, characterized in that the longitudinal axis of the bore (15) located close to the connecting end area (20) of the contacting pin (17) is placed obliquely on the plane of the close-to-connecting area located side (23) of the carrier, respectively of the respective bore plate (11). 25. Contact-making device as claimed in any of the claims 8-24, characterized in that the longitudinal axes of the bores (15; 16) of the carrier (14) located close to the probe end regions (21) and / or the connecting end regions (20). ) are positioned perpendicular to the plane of the sides (24; 23; 23 ·) of the support located close to the respective bores, respectively of the respective bore plate and bore plates, respectively. Contact-making device according to one of the preceding claims, characterized in that the contact pin is provided with one or more open deflections (22). Contact making device according to claim 26, characterized in that the contact pin (17) is provided with at least one V-shaped protrusion. 28. Contact-making device according to claim 26, characterized in that the contact pin (17) is provided with at least one Ü-shaped protrusion (22). Contact making device according to one of claims 1 to 25, characterized in that at least one bent-out region (22) of the contact pin is formed by at least one turn of a metal wire. 30. Contacting device according to one of claims 7-29, characterized in that the bore patterns of both bore plates are identical. 15 Contact making device according to one of Claims 7-29, characterized in that the bore patterns of the two bore plates (11, 12) are of different sizes, preferably that the contact points (17) of the contact pins (17) are close to the 20 points of contact (17). located bore plate (12) has the smaller bore pattern. 32. Contact making device according to one. of the preceding claims, characterized in that the wire 25 of the contact pin is of solid round wire. Contact making device according to one of Claims 1 to 31, characterized in that the wire of the contact pin is made of solid flat wire. 30 34. Contact-making device according to any one of the preceding claims, characterized in that the contact pins in the region between the bores of the carrier carrying these pins are provided with electrically insulating coatings in order to prevent neighboring contact pins from accidentally contacting each other. come. Contact-making device according to one of the preceding 40 claims, characterized in that the front side 8303621-32- (24) and the rear side (23) of the wearer run parallel to one another. Contact-making device according to one of the preceding claims, characterized in that the areas of the support, which comprise the bores for the contact pins, consist of electrically insulating plastic material. 10 Contact-making device according to one of Claims 1 to 35, characterized in that the areas of the support, which comprise the bores for the contact pins, consist of electrically insulating glass. 15 38. Contact-making device according to any one of claims 1-35, characterized in that the areas of the support, which comprise the bores for the contact pins, consist of aluminum, the surface of which is electrically insulated by means of metallic oxidation. 39. Contact-making device according to any one of claims 1-35, characterized in that the areas of the carrier, which comprise the bores for the contact pins, consist of electrically insulating mineral material, preferably of STENAN. 40. Contact-making device according to any one of claims 1-35, characterized in that the areas of the support, which comprise the bores for the contact pins, consist of ceramic material. 41. Contact-making device according to claim 40, characterized in that this ceramic material is porcelain or ceramic oxide material. 42. Contact making device according to any one of claims 1-10 or 14 to 41, characterized in that the connecting end areas (20) of the contact pins (17) protrude beyond the rear (23) of the wearer. 8303621 ^ 33- ^ 43. Contacting device according to any one of claims 7-42, characterized in that the distance between the two bore plates (11, 12) is mutually adjustable and / or the position of the direction of their surfaces is mutually adjustable. 44. Contact-making device according to any one of claims 7-43, characterized in that the two bore plates (11, 12) are placed at a distance from each other such that insertion of the contact pins through the spacing therebetween is made possible in their bores . 45. Contact-making device according to one of the preceding claims, characterized in that the contact pins (17) are detachably placed in the carrier (14). 46. Contact-making device according to claim 1, characterized in that the anti-rotation lock of the contact pin in the carrier is a mechanical form-retaining lock. 47. Contact making device according to claim 1, characterized in that the anti-rotation lock of the contact pin in the carrier is a non-contact locking. 30 8303621