DE19811795C1 - Needle for test adapter for populated or unpopulated circuit boards - Google Patents

Abstract

The needle has a sleeve (4), a wire (2) which is fed into the sleeve and protrudes from at least one end of the needle for contacting a contact point. The sleeve has at least one longitudinal slot (7) in which the wire can bend laterally under an axial load. The sleeve can have several slots in which the wire can bend laterally under axial loads. The slots are arranged in a plane. An Independent claim is also included for a test adapter using the needle.

Description

The invention relates to a needle for a test adapter and a test adapter, which is provided with such needles.

Needles for a test adapter are e.g. B. from US 5,410,260, DE 36 43 305 A1, DE 30 38 937 A1, DE 24 26 337 A1, DD-PS 156 310 and the utility models DE 85 00 168 U1, DE 90 14 236 U1 and DE 195 11 565 U1 known.

All these needles have in common that they each have their own both ends a contact element for contacting one each Contact point and a spring element in the form of a screw have feather. The spring element is between the contact elements arranged so that the contact elements by means the spring against the contact points. The Coil spring can be arranged in a sleeve, with some embodiments, the coil spring from cost and Space is also trained exposed. That between the end contact elements arranged spring element granted the needle has a spring elasticity in the longitudinal direction.

These needles are usually used in pre-test adapters directions for testing printed circuit boards. This Test adapters are between a circuit board to be tested and a basic grid of the test device arranged so that the Needles one contact point each of the test items PCB and the basic grid electrically with each other connect. Between the test adapter and the circuit board or the basic grid can still other elements such. B. a so-called translator. The purpose of this  resilient needles is, height differences between the to balance electrically connected contact points as also a certain, if possible defined contact pressure guarantee.

Such needles provided with coil springs produce in the Usually a contact pressure of about 1.2 N. With an adapter with 4,000 needles give a total pressure of about 4,800 N.

A device for contacting is known from US Pat. No. 3,806,801 the contact points of a microchip that an adapter with only thin, insulated wires that the Contact points of the microchip with those of the test device should connect direction. These wires ensure one elastic spring force by buckling and a little sideways be bent out. Such a device is not for Contacting the contact points of printed circuit boards is suitable because the thin needles do not have the necessary mechanical stability own the larger gaps in the adapters for testing bridging of assembled and bare printed circuit boards. For this, stronger needles would be necessary, which only on their own bend sideways under high force and so much too big Compressive forces between the basic grid and the one to be tested PCB would cause.

EP 0 344 654 A2 describes an adapter for testing conductors known plates, which has relatively strong contact needles. However, these are laterally laterally by means of a clamping plate bent out, whereby to contact the circuit board Clamping plate is loosened somewhat, so that the contact needles with one end pressed against the contact points of the test object become. This device requires to operate the Clamping plate is an additional adjusting mechanism and is therefore Complex compared to conventional test adapters.

The invention has for its object a resilient test Needle for a test adapter for testing assembled or  to create bare circuit boards that have a good, d. H. has relatively soft spring elasticity and is thin is so that they are contacting narrow contact grids allowed. In addition, an adapter with such Needles are created.

The task is carried out by a needle with the characteristics of the Claim 1 solved. Advantageous configurations are in the Subclaims specified. An adapter is in claim 11 specified.

The test needle according to the invention has a sleeve in which a wire is guided, with at least one longitudinal in the sleeve slot is inserted so that the wire is in the area this longitudinal slot bends when an axial force is applied.

The bending area is provided by this longitudinal slot of the wire is determined by the length of the longitudinal slot, so that a thin wire does not have a can bend single bend. The bending length is rather limited to the length of the longitudinal slot. This is it possible to use very thin wires, on the one hand one cause relatively soft spring force and on the other hand one Allow thin overall construction of the needle, so that several Needles can be arranged very close to each other. In addition, the thin wire creates a through its small tip extremely high surface pressure and therefore a very good one electrical contact.

The invention is illustrated below by way of example Illustrated drawings, in which:

Fig. 1 shows a portion of an adapter according to the invention with four needles in cross section, with the needles in the area of a wire leading sleeve are shown along the plane of the slots in section,

Fig. 2, in Fig. Sleeve 1 shown and an adjacent thereto disposed tubes in cross-section, said sectional plane perpendicularly through the sleeve is arranged to the slots of FIG. 1, and for clarity the longitudinal portions of the sleeve and the tube are cut

Fig. 3, the sleeve and the tube of FIG. 1 in cross-section, the cross-sectional plane perpendicular to the slots is arranged,

Fig. 4 is a wire with a protective cap,

Fig. 5 is an end portion of the sleeve of Fig. 1 taken along the plane of the slots in section,

Fig. 6 shows a cross section of the sleeve of Fig. 5 along the line AA, and

Fig. 7 is a force / displacement diagram showing the spring characteristic of the needle according to the invention.

The needle 1 according to the invention for a test adapter has a thin wire 2 which is guided in a sleeve 4 and a tube 5 ( FIG. 1).

The wire 2 is preferably a steel wire with a diameter of 50 microns to 90 microns. In the embodiment shown in the drawings, the wire 2 has a diameter of 70 microns.

The wire 2 is guided in the sleeve 4 , which has at least one longitudinal slot 7 with two slot walls 7 a and a slot bottom 7 b ( Fig. 5). The longitudinal slot 7 extends only over a fraction of the length of the wire 2 , and is preferably in the range from 1/10 to 1/30 of the wire length. In the illustrated embodiment, the slot length is 3 mm and the wire length is 61.5 mm. The slot width ( FIG. 6) corresponds at least to the wire thickness, so that the wire 2 can move into the longitudinal slot 7 . The slot width is preferably about 10% to 20% larger than the wire thickness. In the present exemplary embodiment, the slot width is 80 μm.

In an advantageous embodiment, the sleeve 4 can be provided with a plurality of longitudinal slots 7 , which are arranged on the sleeve 4 in a common slot plane, alternately in the opposite walls of the sleeve 4 and adjoining one another in the longitudinal direction. With such an arrangement, the wire 2 bends in the slots 7 with short successive arcs approximately in the form of a sine curve.

In the embodiment shown in the drawings, the sleeve 4 has an outer diameter of 0.48 mm and an inner diameter of 80 microns, with the introduction of the slots 7, the sleeve 4 does not have a closed pipe section, so that the inner diameter only as the clear width between the groove bottoms 7 b of two adjacent slots 7 comes into play. The length of this sleeve 4 is 29 mm and it is provided with nine 3 mm slots. The number of slots and the slot length depends in particular on the flexural strength of the wire 2 and thus on the wire diameter. Furthermore, when choosing the number and length of the slots, the desired spring stiffness of the entire needle must be taken into account.

For reasons of production engineering, the slots 7 are chamfered on their longitudinally delimiting transverse edges 8 , as shown in FIG. 5.

The sleeve 4 is formed at one end with a recess for receiving an end portion of the tube 5 , which is pressed into the sleeve 4 and is thus formed in one piece with the sleeve 4 .

The tube 5 has an inner diameter which is slightly larger than the diameter of the wire 2 and is 80 microns in Darge presented embodiment. The outside diameter is 0.2 mm.

The wire 2 is guided in the tube 5 without any possibility of evasion, but there is so much play between the wire 2 and the tube 5 that the wire 2 can be displaced in the tube.

At the end of the sleeve 4 opposite the tube 5 there is a recess 9 ( FIGS. 2, 5) for receiving a protective cap 10 . The protective cap 10 has a thin shaft 11 which fits into the recess 9 and is fastened to a contact plug 12 . The protective cap 10 is movably inserted into the recess 9 .

One end of the wire is fastened to the shaft 11 (not shown in FIG. 2), so that the wire is fixed in position with this end by means of the protective cap 10 . The wire 2 is attached to the protective cap 10 , for example by soldering or crimping.

The protective cap 10 essentially has two functions, namely to fix the wire 2 with one end in the recess and to protect the contact points of a basic grid of a test device. These contact points, which are also referred to as pad fields, are usually made of gold and are very often contacted with the needles, so that the contact points would be permanently damaged if they were in direct contact with the thin wire 2 .

The length of the wire 2 is dimensioned such that it protrudes a little at the free end of the tube 5 . At a pressure load of this free, above the tubes 5 end 13 of the wire 2 it is pushed into the tube 5, the wire 2 bends out in the region of the longitudinal slots 7 with short arc approximately in the form of a sine curve. The bending stresses of the individual arches create a spring force that acts against the pressure load.

In the embodiment shown in the drawings, an average spring force of 0.4 N has been set in the tube 5 when the wire is displaced by a distance s of 0.1 to 0.2 mm. As shown in Fig. 7, the contact force of the needle according to the invention remains constant over a wide range of spring travel (from about 0.07 mm to 0.2 mm), so that in an adapter with a large number of needles, even with different ones Due to the spring of the individual needles, a predetermined spring force is set. As a result, predetermined force and pressure conditions are created at all contact points of the test object to be contacted.

In the spring characteristic of Fig. 7 shows a result of frictional forces, hysteresis, so that the spring force upon release of the needle from the contact point slightly lower than when placed on it is.

An adapter with 4000 needles can therefore be used with one force of only 1600 N can be pressed against a circuit board, all needles with the contact points of the circuit board contact a force of 0.4 N. This represents a clear one Reduction of the force required to contact all needles with the contact points of an adapter compared to the adapters described at the beginning with conventional spring needles represents.

In the exemplary embodiment according to the invention, the contact area is only 0.00385 mm ² , so that a contact force of 0.4 N results in a very large surface pressure of approximately 100 N / mm ² .

In Fig. 1 a portion of an adapter 15 is shown having four needles 1 according to the invention in cross section. The adapter 15 has three fixed plates, namely a basic grid plate 16 , a central plate 17 and a test plate 18 . The three plates 16 , 17 and 18 are arranged parallel to each other with a distance of slightly less than half the needle length. In the basic grid plate 16 facing the basic grid of the test device, the ends of the needles 1 having the protective caps 10 are mounted in corresponding through bores. In the test plate 18 facing the test specimen 20, the free ends of the tubes 5 are supported in corresponding through bores. These through holes are chamfered on the side facing the central plate of the test plate 18 to form insertion funnels 22 . The central plate 17 has bores through which the tubes 5 are inserted, the bores being thinner than the sleeves so that the ends connected to the tubes abut the central plate 17 .

In addition to the three fixed plates 16 , 17 and 18 , the adapter has a movable protective plate 24 , which is arranged on the test object side at a distance from the test plate 18 receiving the free ends of the tubes 5 . Spring elements (not shown) are arranged between the protective plate 24 and the test plate 18 , the maximum distance between the two plates 18 , 24 being limited to a maximum distance of z. B. 0.5 mm is limited. This distance defines the spring travel of the movable protective plate 24 relative to the fixed test plate 18 .

The protective plate 24 has through holes in which the free ends of the wires 2 are supported. The wires 2 are arranged displaceably in the through holes and in the unloaded state, the ends of the wires 2 are completely in the through holes. This serves to protect the very thin wires 2 , which can kink laterally even with low transverse loads. When the adapter is placed on a test specimen 20 , the wires 2 are pushed out of the through holes in the protective plate 24 for contacting the contact points of the test specimen 20 . The contact pressure pushes the wires 2 into the tubes 5 and into the sleeves 4 and presses the movable protective plate 24 against the adjacent, fixed test plate 18 of the adapter. The protective plate 24 prevents the free ends of the wires 2 , which otherwise protrude from the tubes 5 without a guide, from buckling laterally.

The configuration of the needles 1 with a sleeve 4 which is thicker in comparison to the tube 5 and in which the wire 2 can move laterally is advantageous since the narrower tubes 5 can be arranged very closely to one another without touching one another. With an oblique position of the needles 1 in the adapter of a specimen can be contacted with a center distance of 0.2 mm with the inventive probes 1 contact points.

The embodiment shown in the drawings test needles according to the invention is a preferred one Embodiment. However, the invention is not limited to limited two-piece embodiment with sleeve and tube; equally it is possible to wrap the wire in one piece from a single slotted tube or one form single slotted sleeve. For the invention essential that the wire through at least one longitudinal slot a limited alternative is offered, so that a very thin wire as a contact element for contacting one Contact point of a device under test can be used by the lateral deflection also the desired spring force generated.

Claims (13)

1. Needle for a test adapter with
a sleeve ( 4 ),
a wire ( 2 ) which is guided in the sleeve ( 4 ) and
protrudes at least at one end of the needle for contacting a contact point, wherein
the sleeve ( 4 ) has at least one longitudinal slot ( 7 ) in which the wire ( 2 ) can bend laterally when subjected to an axial load. 2. Needle according to claim 1, characterized in that the sleeve ( 4 ) has a plurality of longitudinal slots ( 7 ) into which the wire ( 2 ) can bend laterally under an axial load. 3. Needle according to claim 2, characterized in that longitudinal slots ( 7 ) are arranged in one plane. 4. Needle according to claim 2 or 3, characterized in that the longitudinal slots ( 7 ) are arranged adjacent to one another in the longitudinal direction. 5. Needle according to one of claims 2 to 4, characterized in that the longitudinal slots ( 7 ) are arranged alternately in opposite wall regions of the sleeve ( 4 ). 6. Needle according to one of claims 1 to 5, characterized in that the needle has a tube ( 5 ) which is arranged coaxially to the sleeve ( 4 ) and connected to it. 7. Needle according to claim 6, characterized in that the tube ( 5 ) has a smaller outer diameter than the sleeve ( 4 ). 8. Needle according to claim 6 or 7, characterized in that the inner diameter of the tube ( 5 ) is dimensioned such that the wire ( 2 ) is guided therein with some play. 9. needle according to one of claims 6 to 7, characterized, that the wire is a steel wire with a diameter in Range is from 50 microns to 90 microns. 10. needle according to one of claims 6 to 9, characterized, that the tube has an outer diameter in the range of 0.20 mm to 0.30 mm. 11. Adapter with needles according to one of claims 1 to 10, wherein the adapter has three fixed plates, namely a basic grid plate ( 16 ), a central plate ( 17 ) and a test plate ( 18 ), which are arranged approximately parallel to each other and each with Through bores are provided in which the needles ( 1 ) are stored, the free ends of the tubes ( 5 ) being stored in the test plate ( 18 ), and in addition to the three fixed plates ( 16 , 17 , 18 ) the adapters ( 15 ) a movable protective plate ( 24 ) is provided, which is arranged on the test object side at a distance from the test plate ( 18 ). 12. Adapter according to claim 11, characterized in that the movable protective plate ( 24 ) has through bores in which the free ends of the wires ( 2 ) are mounted, so that when the adapter ( 15 ) is placed on a test specimen ( 20 ) the wires ( 2 ) to contact a contact point of the test specimen ( 20 ) a piece from the through holes. 13. Adapter according to claim 11 or 12, characterized in that the distance between the movable protective plate ( 24 ) to the adjacent fixed test plate ( 18 ) in the unloaded state is about 0.5 mm and between the movable plate ( 24 ) and the fixed test plate ( 18 ) a spring element is arranged.