DE3818728A1 - Spring contact pin - Google Patents

Abstract

A spring contact pin for making contact with test items. Said spring contact pin has a straight metallic sleeve which guides a piston of a metallic contact element in a straight line. The contact element projects beyond the sleeve and can rotate about the longitudinal axis of said sleeve. The contact element has an elastically flexible contact needle whose free end is used for making contact with the test items. This end of the contact needle is arranged eccentrically with respect to the longitudinal axis of the sleeve.

Description

The invention relates to a spring contact pin according to the preamble of claim 1.

Spring contact pins are used in so-called test adapters (see eg "KRÜGER test equipment for electrical Testing of printed circuit boards for watches ", yearbook of the German Society for Chronometry, Vol. 30, 1979, S. 269-276) of electrical test equipment used which test facilities the testing of DUTs, such as assembled and unequipped Printed circuit boards, integrated circuits, chips or other electronic or electrical or bare test objects for electrical Serve without errors. The spring contact pins serve doing the making of electrical contact connections to predetermined positions of the respective test object, the with the help of the metallic spring contact pins with an evaluation device or test device or other suitable circuit arrangement of Test facility can be electrically connected. To Establishing the electrical connections then leads  the test device, evaluation device or the other Circuit arrangement testing the relevant Test specimen for electrical freedom from errors.

Such test adapters generally have a large size Number of such spring contact pins, usually several Hundreds to several or many thousands. A with Spring contact pins equipped test adapter is used in the general testing a very large number of DUTs of the same type, so that the Spring contact pins always on themselves corresponding, equal or approximately the same trained positions of the test objects. The Number of those to be tested by a test adapter UUTs of the same type are usually several to many thousands, often even millions. It is important that the spring contact pins as long as possible Have a lifespan and preferably do not fail, as long as the test adapter test objects of the same type checks, otherwise incorrect checks can occur or cumbersome replacement of the damaged or destroyed spring contact pin is necessary. Here need the spring contact pins for safe electrical Contacting the examinee, often also To penetrate dirt or oxide layers on the test object are with relatively large contact forces on the Press test specimen, e.g. with 30 per spring contact pin up to 300 cN. The spring contact pins have extremely small maximum outer diameter because the places to be contacted by the test subjects in the Usually at very close intervals are arranged, often at points of a grid, for example.  a grid dimension of 1 to 3 mm. Spring contact pins Therefore, in general, only a very small maximum Outside diameter usually less than 3 mm have, preferably outside diameter of about 0.8 to 2.5 mm. Their lengths can be, for example, 2 to 12 cm. In some cases, these dimensions can also exceed or fall below.

In the known spring contact pins in the Preamble of claim 1 mentioned type, that is are equipped with resilient contact needles, the resilient contact pin is straight and coaxial to the longitudinal axis of the sleeve in the carrying it Part of the contact member firmly used, the Has piston of this contact member. The front one free end area of the resilient contact needle is like with sewing needles steadily tapered, so that this taper slightly longitudinally convex in longitudinal sections Has contour. Such spring contact pins are especially used when it comes to dirt and oxide layers on the areas to be contacted of the respective test object. But when the contact needle at an angle to its longitudinal axis sloping or curved surface, it can due to her resilient flexibility by her Contacted surface significantly bent out to the side be, causing wear on this free, pointed tapered end area of the contact needle as well as on Piston and the piston raceway of the sleeve strong can be enlarged. Also this side Bend out or stress the contact needle relatively strong lateral forces, as it often depends on the number  of the test objects to be tested often hundreds of thousands of times or can occur millions of times, including fatigue fractures to lead.

It is an object of the invention in one Spring contact pin of the type mentioned structurally simple, reliable manner aforementioned disadvantages of the known Reduce or avoid spring contact pins.

This object is achieved by a Spring contact pin according to claim 1 solved.

By at least one the free end of the contact needle End area of the contact needle is eccentric is arranged, the contact member by test specimens, where the free front end of the contact needle sloping or arched surfaces from them so that they bend the contact needle out laterally, automatically when contacting the test objects in a Rotated position in which this deflection of the Contact needle is practically minimal. For this, in in many cases a single contact such an inclined or arched point of a Test specimen through the relevant spring contact pin, around during the stroke caused by this specimen of its contact member relative to the sleeve Already turn the contact member in this position the the lateral deflection of the contact needle approximately is minimal or because the test items are the same among themselves and therefore the contact needle always on the same slope Surfaces or similarly curved surfaces of the test object  occurs, it is also sufficient if only through the Contacting several test subjects the one in question Contact member is rotated into the position in which the lateral deflection of his contact needle through the Test subject has become approximately minimal. Such oblique points on test specimens that the contact needle Bend the spring contact pin sideways, for example. Soldering points, sloping tracks, to be contacted sloping or arched areas on a circuit board or another carrier arranged electrical Components, such as feet of electrical components or other parts, bore edges of contacts that be contacted laterally, etc.

By the spring contact pin according to the invention in Operation behaves so that its contact needle at the Testing of test objects automatically in a Position is rotated in the lateral deflection the resilient contact needle practically minimal is the wear of the in contact with test objects coming free end of the contact needle of the Contact member and the wear of the piston of the Contact member and its sliding Piston travel of the sleeve significantly reduced. These Wear reduction increases the lifespan of the Spring contact pin considerably and also works favorable in that the electrical Contact resistance from the contact member to the sleeve is reduced or longer than before stays or rises less quickly than before. Also is the risk of fatigue fractures eliminated or at least reduced.  

In the subclaims there are some advantageous ones Developments and refinements of the invention described.

The measure according to claim 2 results in relatively large Eccentricity with the resulting Advantages.

The contact needle can preferably be a single free one Have lace or have other training, For example, it is often expedient to use a preferably sharp-edged one Cut or free at least two points Have end area.

It has already been mentioned that the spring contact pins generally at very close centers can be arranged side by side, so that also towards make sure that there are no electrical contacts can come between adjacent spring contact pins. Here it is particularly favorable to provide that the Contact needle completely within one through the largest outer diameter of the sleeve of the Spring contact pin, coaxial to it geometric circular cylindrical surface, located preferably the maximum eccentricity of the Contact needle smaller than 0.9 times the radius this geometric circular cylindrical surface is preferably less than 0.8 times the radius corresponds to this circular cylinder area. Then she can still slightly bent to the side during operation without getting out of this circular cylinder surface  get or exceed them significantly what causes it even with extremely dense arrangement of the Spring contact pins next to each other not for mutual contact of contact pins can.

Preferably, the largest diameter of the free lying area of the contact needle smaller than that 0.7 times the diameter of the at least one sliding surface the piston of the contact member, preferably the same or less than 0.5 times, particularly suitably the same or smaller than 0.3 times its diameter Rotation of the contact member enables sliding surface.

The contact needle can preferably be straight. This is structurally simple and enables axially rigid Behavior of her when she is on a perpendicular to her Surface of the test object hits, which is advantageous.

If the contact needle, which is particularly advantageous, is arranged axially parallel to the longitudinal axis of the sleeve, In this case, the measure can also be carried out Claim 10 can be provided, since this is particularly so large eccentricity of the contact needle axially parallel arrangement of the just formed Contact needle is possible. However, this measure is even with differently designed and arranged Contact needles are also useful.

In some cases it is useful if at least an area of the contact needle obliquely to the longitudinal axis of the Sleeve is directed or continuously curved. Hereby  can e.g. achieve that the contact needles in a blind bore coaxial to the longitudinal axis of the piston of the contact member can be used firmly and still her free end eccentric with respect to this longitudinal axis is arranged. Here you also achieve what in in some cases it is useful that this contact needle then can spring axially in the manner of a spiral spring and no longer behaves axially rigid when you front free end on one to the longitudinal axis of the sleeve vertical surface of the test object occurs. In fact need spring contact pins according to the invention of course not just contacting sloping or arched ones Places to serve test subjects, but can also serve to contact places of the examinees who Do not bend the contact pins out to the side.

The contact needle can preferably be a cylindrical, particularly useful circular cylindrical Have needle area that is essentially over the length of the area of the Contact member of the protruding area of the contact needle extends. Instead of this area circular cylindrical If necessary, he can also train other training have, for example. oval or other non-circular Cross-section. It is special with a straight contact needle useful if they are over their length except its free front end area is cylindrical, is preferably circular cylindrical, which is particularly easy to manufacture.

The contact needle can expediently directly on the piston of the Be arranged contact member, preferably in a  Hole must be firmly inserted by him, for example or in any other way in the blind hole be attached. However, it is also possible that Contact needle on a protruding from the piston To arrange the area of the contact member.

The contact needle can preferably be an unthickened one have free end, particularly useful at all have no thickening along their length, what their Manufacturing simplified. It is also for that Intended contacts particularly cheap if on front end of the contact needle to the free End of the contact needle only one, preferably rotationally symmetrical, tapering taper Contact needle leads, which, for example, expediently conical can be formed, or continuously in longitudinal sections convex, for example like the tips of sewing needles, or can be concave or other suitable May have training. This not only simplifies the manufacture, but is also possible with respect slight lateral bending of the contact needle and particularly good contact of sloping surfaces from DUTs cheap.

Depending on what is desired and practical, a test adapter can only be equipped with spring contact pins according to the invention or, in addition to at least one spring contact pin according to the invention, can also have a more or less large number of differently designed spring contact pins.

In the drawing, embodiments of the Invention shown. Show it:

Fig. 1 is a spring contact pin in longitudinal section according to a first embodiment of the invention,

Fig. 2 is a plan view of the spring contact pin according to Fig. 1,

Fig. 3 shows a spring contact pin in longitudinal section according to a second embodiment of the invention,

Fig. 4 is a plan view of the spring contact pin according to FIG. 3.

Fig. 5A is a side view of a contact member according to another embodiment of the invention, the remaining parts of the spring contact pin are not shown,

FIG. 5B is a section of the contact needle of FIG. 5A, as viewed in the direction of arrow C,

Fig. 6 is a partial side view of a contact member according to a further embodiment of the invention with a contact needle with a two-pronged free end region, the remaining parts of the spring contact pin are not shown.

The metallic spring contact pin 10 shown in FIGS. 1 and 2 has a sleeve 11 which consists of an essentially circular-cylindrical jacket 9 which is completely open at the top and a base 12 . The jacket 8 has a circumferential annular groove 13 arranged at a distance from the upper open end 14 of this sleeve 11 . This metallic sleeve 11 can preferably be formed in one piece from a circular cylindrical tube.

In this sleeve 11 , the metallic piston 17 of a two-part contact member 16 is axially slidably mounted with plain bearing play, which is by a seated on the bottom of the sleeve 11 , preloaded helical compression spring 15 in the rest position of the contact member 16 to the stop forming for him, through the circumferential annular groove 13 formed inner annular bead of the sleeve 11 is pressed to limit the upward movement of the contact member 16 .

The piston 17 of this contact member 16 is formed by two piston sections 19 , 19 'and one connecting them, reduced in diameter, to them coaxial connecting rod 20 . This piston 17 is in one piece and the circular cylindrical peripheral surfaces 18 of its piston sections 19 , 19 'form the sliding surfaces of this piston 17 , which can slide on the inside piston raceway of the sleeve, the contact member 16 can also rotate about the longitudinal axis 26 of the sleeve 11 . The lower piston portion 19 'is pressed by the biased spring 15 to the formed by the groove 13 , hereinafter also designated 13 annular bead-like stop 13 in the rest position of the contact member 16 to limit its movement in the outward direction. The upper piston section 19 can limit the downward movement of the piston 17 by coming into contact with the stop 13 in the downward direction, so that the possible stroke of the piston 17 is determined by the length of the connecting rod 20 minus the width of the stop 13 .

As a second one-piece part, the contact member 16 has a straight, metallic, spring-elastic contact needle 21 with an unthickened, conical (conical) tip 22 at its free end region. This straight contact needle 21 is made, for example, of hardened steel, tempered copper beryllium or the like. The piston 17 can also consist of steel, tempered copper beryllium or the like. It is also possible to provide the sleeve 11 and / or the contact member 16 at least partially with coatings which reduce the electrical contact resistance between the piston 17 and the sleeve 11 .

The contact needle 21 is arranged axially parallel to the longitudinal axis 26 of the sleeve 11 , the distance of the longitudinal axis 26 from the longitudinal axis 32 of the contact needle e . As a result, the contact needle 21 is arranged eccentrically with respect to the longitudinal axis of the piston 17 and thus the longitudinal axis 26 of the sleeve 11 , specifically with the eccentricity e , so that the tip 22 of the contact needle 21 is arranged eccentrically with respect to this longitudinal axis 26 . The eccentricity e corresponds to the distance between the front end 33 of the tip 22 and the longitudinal axis 26 of the sleeve 11 .

The eccentricity e can preferably be at least 0.4 times the radius of the two piston sections 19 , 19 '. The eccentricity e can preferably be 0.5 to 0.8 times this radius, but in many cases it can also be expediently larger or even smaller.

The length of the area of the contact needle 21 projecting beyond the piston 17 can preferably be approximately 5 to 25 mm, but may also be greater or smaller, if necessary. The diameter of this contact needle 21 is expediently considerably smaller than that of the piston sections 19 , 19 ', that is, the largest diameter of the contact member 16 here is substantially smaller than the radius of the piston sections 19 , 19 ', and here less than half this radius. The eccentricity e in this embodiment is approximately 0.6 to 0.7 times this radius.

By in this advantageous embodiment, the opening 14 of the sleeve 11 penetrated by the contact member 16 , specifically here by the contact needle 21, corresponds in its clear inside diameter to the inside diameter of the circular cylindrical inner wall surfaces of the maximum inside diameter of this sleeve 11 , approximately maximum eccentricity e can be achieved Reach the longitudinal axis of the sleeve 11 axially parallel straight contact needle 21 . This is particularly favorable for the self-adjustment of this contact needle 21, which is described in more detail below, when contacting test specimens, one of which is indicated by dash-dotted lines at 25 in FIG. 1 and which presses the contact needle 21 downward in the direction of arrow B when it comes into contact, such as will be explained in more detail and also has the advantage that the contact needle 21 behaves axially rigid when contacting surfaces of test specimens perpendicular to its longitudinal axis, that is to say it is not bent out at all.

If, on the other hand, the contact needle 21 occurs on a point of a test specimen 25 to be contacted by it, which is inclined as shown in FIG. 1, for example on an inclined foot of an electrical component fastened on the board of an assembled printed circuit board, then it becomes during contact this inclined surface or possibly in the course of the successive contacting of several such inclined surfaces of test specimens, which are tested one after the other and are exactly the same among themselves, rotated together with the entire contact member 16 so that they are as little as possible laterally through this incline when contacting the test specimen is bent out. This reduces their wear and the risk of fatigue fractures. In this embodiment, in order to explain this in more detail, it is assumed that when the contact needle 21 first encounters the slanted surface 34 shown, it is still in the dash-dotted position 21 ' in which it is when the contact member 16 is not rotating would, would relatively strongly deflect laterally upon contacting this Prüflinges 25, which could result in a lot of repeated contact of such samples in this situation, excessive wear and possibly also to the fatigue of the contact needle 21st The contact needle 21 can, for example, have a diameter of 0.08 to 0.8 mm or even smaller or larger diameters depending on the application.

In practice it is normal that such a Spring contact pin often many thousands or even Millions of candidates for the same training has to contact, so always with those among themselves same test subjects then in the same place on the DUT occurs.

The described advantages of spring contact pins according to the invention can be achieved with an extremely simple design of the spring contact pin, as shown, for example, by the exemplary embodiment according to FIGS. 1 and 2, but also the exemplary embodiment according to FIGS. 3 to 6. Namely, the contact members 16 are inexpensive to manufacture and the sleeve 11 and the spring 15 can be of a type which is conventional per se.

The spring contact pin 10 shown in FIGS. 3 and 4 differs from that according to FIG. 1 in the following details. The sleeve 11 does not have an annular bead serving as a stop on the inside, but is somewhat flanged inwards at its upper end and this ring-shaped flare 29 forms a stop for the piston, which consists here of only a single circular cylindrical part and is constantly loaded by the prestressed helical compression spring 15 17 of the contact member 16 . The crimping 29 of the sleeve 11 , however, no longer makes it possible to arrange the contact needle 21 as in FIG. 1 with greater eccentricity e , parallel to the axis 26 of the sleeve 11 . It is therefore firmly inserted into a blind bore of the piston 17 coaxial to the longitudinal axis 26 of the sleeve 11 , for example pressed in and angled outwards at an angle, with its free end region, the rotationally symmetrical tip 22 , which in turn is thickened and weakly convex in the longitudinal center planes is formed in this embodiment is directed so that the longitudinal axis 32 'of this tip 22 is axially parallel to the longitudinal axis 26 of the sleeve at a distance from the eccentricity e . If necessary, the longitudinal axis 32 'of this tip 22 may be aligned with the longitudinal axis of the inclined portion 35 of this contact needle 21 and then the eccentricity e is the distance of the front end of the tip 22 from the longitudinal axis 26 .

When contacting inclined or curved surfaces of the test object, the eccentricity e also present at the tip of the contact needle also causes the contact member 16 to always be rotated when contacting test objects into a position in which the lateral bending of the contact needle 21 caused by the test object is minimal what has the advantages already described above.

In both exemplary embodiments according to FIGS. 1 to 4, the contact needles 21 are located entirely within geometric circular cylindrical surfaces, such as 27, defined by the circular-cylindrical outer peripheral surfaces of the sleeves 11 , which has the advantages described above.

In Fig. 5A and 5B, a contact member 16 is shown a spring contact pin, not shown in further detail, that of the contact member 16 of FIG. 1 and 2 differs only in that the front free end region 22 of the contact needle is flattened 21 under broadening and has a sharp cutting edge 37 that runs perpendicular to the longitudinal axis 32 of the contact needle, which in this exemplary embodiment is directed radially to the longitudinal axis 26 of the piston 17 , but can also have a different arrangement.

The contact element 16 shown in FIG. 6 has at least two pointed prongs 39 separated from one another by at least one incision 40 , preferably a total of two prongs 39 separated from one another by an incision 40 , on the free, front, thickened end region 22 .

In FIGS. 5A and 6, the eccentricity e are the contact pins 21 is also shown, each correspond to the distance between the longitudinal axis 26 of the piston 17 and thus the sleeve of the respective spring contact pin, not shown, and the longitudinal axis 32 of the contact needle 21.

It should also be mentioned that the rotation of the contact member 16 is facilitated or made possible at all by, as is known, when contacting test objects, the respective test object pushes the contact member 16 further against the force of the spring 15 of the spring contact pin 10 into the sleeve 11 , the piston 17 in this case slides in the sleeve 11 with plain bearing play and this sliding friction of the piston 17 at least facilitates the rotation of the contact member 16 into the respective angular position in which the contact needle 21 is least laterally bent out by the areas of the test specimens in contact with it.

A particularly important advantage of the invention Spring contact pins is also the following. Electrical or electronic components like resistors, Capacitors, inductors, etc. are normal with legs, the holder and their Solder to the circuit board or the like. Serve. Most of time has the circuit board or the like for each such a leg a hole through which the leg is stuck through and on the back of it concerned circuit board with its free end survives and here is the leg with one Conductor track or the like soldered by a solder spot, over the free end of the leg, however usually survives something. If now with the previously known spring contact pins, in which the straight Contact needle coaxial to the sleeve and thus to the piston  is arranged, such a contact needle centrally hits such a free end of a leg, then this leg makes it strong laterally distracted, with the consequence of high wear frequent distraction as well as the risk of Fatigue breaks or immediate breaks in the Contact pin. It can also cause permanent bending of the Contact pins come in when their spring elasticity is there is exceeded. The also avoids this Spring contact pin according to the invention, as a result of Eccentricity of at least the free end area of the Contact pin usually doesn't turn on at all such a leg of an electrical component strikes, but due to the eccentricity laterally passing him directly to the one in question Hits the solder joint. If he does, however, on the leg hits or on a correspondingly steep slope the solder joint, then the contact pin becomes automatic due to the eccentricity of its free end area around the longitudinal axis of the sleeve of the spring contact pin turned and his contact pin no more or only even less bent, so that the aforementioned Disadvantages of the known contact needles Spring contact pins no longer occur or strong be reduced.

Claims (14)

1.Spring contact pin for contacting electrical or electronic test objects, such as printed circuit boards, chips, integrated circuits or other electrical or electronic assembled or unassembled test objects, which spring contact pin has a straight metallic sleeve which guides a piston of a metallic contact member in it axially slidably, which contact member protrudes beyond the sleeve and can be moved further into the sleeve against the force of at least one spring by the respective test specimen and which contact member can also be rotated about the longitudinal axis of the sleeve and this contact member has an elastically flexible one-piece contact needle which is attached to a part of the support Contact member is fixedly arranged, wherein the front end of the contact needle serves to come into contact with test specimens, characterized in that at least one end region ( 22 ) of the contact needle to the longitudinal axis ( 26 ) having the free end of the contact needle ( 21 ) the sleeve ( 11 ) is arranged eccentrically. 2. Spring contact pin according to claim 1, characterized in that the eccentricity ( e ) of the free end region ( 22 ) of the contact needle ( 21 ) is at least 0.4 times the maximum radius of the piston of the contact member, preferably about 0.5 - up to 0.8 times this radius. 3. Spring contact pin according to claim 1 or 2, characterized in that the contact needle ( 21 ) is straight and / or at least its area projecting beyond the area of the contact member carrying it is unthickened. 4. Spring contact pin according to one of claims 1 to 3, characterized in that the contact needle ( 21 ) has a cylindrical, preferably circular-cylindrical longitudinal region which extends substantially over the length of the region of the contact needle projecting over the region of the contact member ( 16 ) carrying it extends. 5. Spring contact pin according to one of the preceding claims, characterized in that the contact needle ( 21 ) has a single tip ( 22 ), preferably this free tip of the contact needle from a substantially constant cross-section of the contact needle extending over the length of the contact needle ( 21 ) tapers out to its free single end, preferably this tip ( 22 ) is rotationally symmetrical, in particular conical, or has a curved contour in the longitudinal center planes. 6. Spring contact pin according to one of claims 3 to 5, characterized in that the straight contact needle ( 21 ) is arranged parallel to the longitudinal axis ( 26 ) of the sleeve ( 11 ). 7. Spring contact pin according to one of claims 1 to 6, characterized in that the contact needle ( 21 ) is arranged at least partially obliquely to the longitudinal axis of the sleeve ( 11 ). 8. Spring contact pin according to one of the preceding claims, characterized in that the contact needle ( 21 ) on the piston ( 17 ) of the contact member is arranged. 8. Spring contact pin according to one of the preceding claims, characterized in that the piston ( 17 ) of the contact member is preferably completely inside the sleeve ( 11 ) and two spaced-apart piston sections ( 19 , 19 ') with circumferential, sliding on the Piston raceway of the sleeve serving sliding surfaces, which piston sections are interconnected by a reduced diameter section ( 20 ) of the piston ( 17 ) and that the sleeve ( 11 ) in the region of this central section ( 20 ) has a stop ( 13 ) for the contact member ( 16 ). 10. A spring contact pin according to claim 9, characterized in that the internal diameter of the penetrated by the contact member (16) opening (14) at least equal to the sleeve (11) about the diameter of a sliding surface of the piston of the contact member (16). 11. Spring contact pin according to one of the preceding claims, characterized in that the contact member is composed of a total of two one-piece parts, namely from the contact needle ( 21 ) and the part carrying it ( 17 ). 12. Spring contact pin according to one of the preceding claims, characterized in that the contact needle ( 21 ) is completely within a by the largest outer diameter of the sleeve ( 11 ), to it coaxial geometric circular cylindrical surface ( 27 ). 13. Spring contact pin according to one of the preceding claims, characterized in that the largest diameter of the free area of the contact needle ( 21 ) is smaller, preferably substantially smaller than the diameter of the at least one sliding surface ( 18 ) of the piston ( 17 ) of the contact member ( 16 ) , preferably a maximum of 0.5 times, in particular a maximum of 0.3 times the diameter of this at least one sliding surface ( 18 ). 14. Spring contact pin according to one of claims 1 to 4 or 6 to 13, characterized in that the free end of the contact needle ( 21 ) is designed like a knife or has at least two prongs ( 39 ).