DE3541251C2 - - Google Patents

Description

The invention relates to a contacting device for an IC test socket, consisting of base plate, contacting rich and cover plate, with an ejector and angled between the Contacting area and the base plate arranged contacts made of tape material, the contacts in the socket body of the contact tion area are movably supported.

Such contacting devices can be used in many different ways for installation in test facilities for quality testing and for te Most of electronic circuits (IC = Integrated Circuit) Ver find application.

This is particularly the case with the components in the new Techniques such as PLLC (Plastic Leadless Chip Carrier), CLCC (Ceramic Leaded Chip Carrier), SO (Small Outline) or SMD (Surface Mounted Device), there are several problems:

These are relatively small components with i. d. R. very many contact connections. Although these components are very large Having manufacturing tolerances is therefore nonetheless exact positioning is necessary. To make matters worse, the contacting can be arranged on four sides of the component can. There is also a so-called Kelvin contact in the test version desired to measure current and voltage at the same time To enable testing.  

Furthermore, there is high temperature resistance for the test version the contacting device desired, for example in Testing machines for the IC test at elevated temperatures and for the to be able to install burn-in test. (burn-in: in the quality assurance Storage of components at high temperatures. In doing so thermal failures before the practical use of elimi kidney. Taken from: Lexicon of modern electronics, market & tech nik-Verlag, Munich, 1980).

Since the contacts of the components are preferably in a tin-plated version abrasive contact is required Lich to switch off oxidation-related contact resistances.

Kontaktie are for use with components in the so-called DIL version stanchions common to the side of the contacts of the components be pressed, this being done via a driven mechanism and the contact pressure can be adjusted if necessary.

Such a contacting device is for example from the US-PS 41 93 656 known, which shows a large-area ejector, which, however, is only suitable for components that are on two each other opposite sides with a large number of contacts are seen.

Such systems are, however, in the case of construction elements on all four sides are provided with contacts, very complex to implement, especially Different component sizes exist, and also large tolerances zen are to be mastered.

Contacting in test bases is possible in principle, it throws however problems with the permanent load and a desired automa tization due to oxidation of the contacts during all if only very short scraping contact is not excluded can be.

With the existing solutions  is a miniaturization of the contact system due to the large number of contacts necessary, because of the round contact wires used the There is a risk of lateral contacts evading, al is common, however, the fine contacts laterally in a cross group in order to achieve better leadership. The the necessary exact positioning is problematic, because the component tolerances are up to 50% of the contact distances can.

Automation continues to pose the difficulty that the commonly used ejector, usually by means of Füh is in the base plate of the contact socket, Prob leme with regard to pollution and the prescribed temperature changes in an interval from -55 to +155 degrees C if small components are to be tested.

The present invention is therefore based on the object Find contacting device in the intended applications cases of testing of components with many connections up to four pages, under thermal stress and when desired Kelvin contacting accurate and safe contacting of the allows testing components.

To solve this problem, the invention provides that Contacts are designed as leaf springs with a rectangular cross section, that the cross section of the ejector according to the dimensions of the component to be contacted is dimensioned and that the deck plate has a feed channel in which the components laterally can be fed in and out.

Advantageous developments of the invention are in the dependent claims Chen specified.

The proposed solution is the contacts as Blattfe training, which makes contacting more secure than with run  the or oval wires is possible because the leaf spring contacts we are considerably more stable and due to this design also one have a larger contact area. To make this possible the guides of the leaf spring contacts both in the socket body of the Contact area as well as in the base plate not in one Level arranged, but offset in two below or next to each other mutually arranged levels, which is a maximum width of the contacts enabled in the contact area. So that the recording in the socket body is possible in two levels, either the contacts of the bottom swinging backwards or the contacts step the top row away from the guide groove  curved downwards.

Both contact spring systems open outwards in the lower area cranked back, with this arrangement, the ejector mechanism a lot of space inside the contact assembly.

The ejector, the same size in cross section as the one to be tested Has component, is pushed out by ejector springs fills the space between the contact springs, as a kind of placeholder out. The ejector springs are in the corners of the ejector body arranged. This enables the ejector to be floatingly supported body, which is guided by the resilient contacts. A Forced guidance by means of a guide pin in the base plate, the possible It is not necessary to prevent the ejector body from tipping over. The Base plate can therefore be easily dust and gas tight compared to the test facility to be trained.

Due to the compact arrangement of the leaf spring contacts on the respective The ejector springs can also have rims on the frame be moved further into the body of the foundation. This arrangement is very practical for components with small dimensions, since here the Accordingly, the inner ejector cross-section is also very small must be sioned, so that an accommodation of the ejector mechanism in the technology previously used would be difficult.

Since the ejector body in the area of the contacting has roughly the outer dimensions of the IC to be contacted, the contact springs can inside (biased towards the component). The preload can are generated, for example, in that the contact springs on the Exit point from the base plate by a certain angle, e.g. B. 10 Degrees, to be bent inwards.

The preloaded contact springs are accordingly on the ejector body so that when inserting the item to be checked (or contacted) Component of the ejector body only the space for the component releases so that the biased contact springs the insertion of the Component in the contact can not hinder.

At the same time due to the wide contact springs due to the leaf spring design with rectangular cross-section a lateral jamming or slipping avoided even with differently tolerated components.

Furthermore, because of the biased contact springs when inserting the Component a scraping contact with the contact tabs of the Component possible, which enables good contact.  

The contacts themselves are also kept clean by the ejector because this past the contact with the edges with each actuation scrapes.

Another advantage of the ejector shape is that the insertion opening in the contacting of the ejector almost completely is covered, so that thereby the movement of the component to be tested does not experience any obstruction in the feed channel to the contact arrangement. The Components slide cleanly over the covered contact point. This enables use in testing machines where the feeding of the components takes place automatically, as a result of this there is little interference maturity with regard to the transport of components is to be expected. The contacts according to the invention can be used for a so-called Kelvin contact Use if the upper parts guided in the base face outwards for example, be returned to the base plate. From a Kelvin cone Clocking is spoken when on a component contact because of the test contact arrangement at the same time z. B. a current and a Voltage measuring arrangement finds place.

The contacting device according to the invention is in the exemplary embodiment below outlined for the recently used SMD components. Of course, the arrangement found is not four-sided on this components provided with contact connections, but can also for example for components with two-sided or also one-sided attached contacts can be modified accordingly.

Details of an embodiment of a contacting device according to the invention are described below in connection with the attached drawing described. It is shown here in

Fig. 1 is an elevational view of the contacting device in section,

Fig. 2 is a plan of the contacting device, with the cover plate on the left side and on the right side the guide part is partially removed.

In the version 1 of the contacting device, a socket body with base body 4 and guide part 5 and a cover plate 6 are fastened on a base plate 3 .

Depending on the requirements, metals are used as materials for the frame parts (conductive) or plastics (insulating) or ceramic parts (insulating rend and wear-resistant) usable.

An ejector 7 is mounted on the base plate 3 with the ejector springs 8 , which are arranged in the corners of the ejector 7 . The ejector 7 lies within the contacts 8 and 10 , which are arranged on the four sides of the socket body.

A possible variant in which the ejector 7 has diagonally arranged arms 7 a in the corners, the ejector springs 8 a then being placed further outwards is indicated on the right-hand side of FIG. 2.

The ejector 7 closes the contact point opposite the Zuführka channel 6 a, which is incorporated in the cover plate 6 , flush from the edge.

On the left side of FIG. 1, the arrangement of the contacts 9 is evident:
Each contact 9 is mounted in the guide part 5 in guide grooves and is covered by the cover plate E. At the contact point 9 a, the contact spring is bent with a radius and lies against the side edge of the ejector 7 , wherein it is then cranked back to the socket body and is guided through the base plate 3 at points 9 c. Connections for test and measuring devices can be made at the contact ends 9b. If Kelvin contacting is required, the contacts can be extended by means of the guide grooves in the guide part 5 (reference number 9 d), in which case they can then be returned to the base plate.

The arrangement of the contacts 10 can be seen on the right side of FIG. 1:
Each contact 10 is mounted in guide grooves, which are arranged in the guide part 5 and are covered by the base body 4 , so as to be longitudinally movable. To lead to the contact point, the contact spring at point 10 a is bent upwards with a radius and is guided past the cover plate 6 back past the contact point on the side edge of the ejector 7 . With a smaller offset towards the base, the contact spring is guided through the base plate 3 .

The offset arrangement of the leaf spring contacts 9 , 10 in the base plate can be seen in FIG. 2 in the lower part.

The possible close contact configuration is indicated on the left side of FIG. 2.

As a material for the leaf spring contacts Usually copper beryllium is used.

When using the contact arrangement, for example in an automatic test facility, the following process takes place:
The IC 2 to be tested is brought up in the feed channel 6 a (eg by gravity, if the contact arrangement is installed accordingly see arrows "Zu" in Fig. 2) and stopped at the contact point by suitable means, not shown. With a plunger (also not shown), the component is pressed in the direction "K" into the contacting, the ejector 7 being moved against the forces exerted by the springs 8 and releasing the contact for the component. The component slides in sliding contact with its contact elements in the contact with the contacts 9 , 10 of the contact arrangement. Since the contact springs 9 , 10 are arranged in a spring-loaded manner, they are pressed against the contact elements of the component. The component can now be tested with test means which are connected to the contacts protruding through the base plate 3 in accordance with 9 b. When the test is finished, the plunger is withdrawn and the component 1 is returned to the feed channel 6 a by the ejector 7 in the direction "A". The ejector covers the insertion opening flush with the edge, so that the component can be transported downwards without hindrance, for example to another sorting device or the like, cf. Arrows "Ab" in Fig. 2.

Claims (14)

1. Contacting device for an IC test socket, consisting of base plate, contacting area and cover plate, with an ejector and angled between the Kontaktierungsbe rich and the base plate arranged contacts made of tape material, the contacts being movably mounted in the socket body of the contacting area, thereby featured,
that the contacts ( 9 , 10 ) are designed as leaf springs with a rectangular cross-section,
that the cross section of the ejector ( 7 ) is dimensioned according to the dimensions of the construction element to be contacted ( 2 ) and
that the cover plate ( 6 ) has a feed channel ( 6 a) in which the components ( 2 ) can be fed in and out laterally. 2. Contacting device according to claim 1, characterized in that the socket body from a base body ( 4 ) and a guide part ( 5 ) with incorporated slots for receiving the contacts ( 9 , 10 ) and a base plate ( 3 ) is built up. 3. Contacting device according to claim 1 and 2, characterized in that the contacts ( 9 , 10 ) alternately in the solution body between the guide part ( 5 ) and cover plate ( 6 ) or guide part ( 5 ) and base body ( 4 ) are longitudinally movable . 4. Contacting device according to claim 1 to 3, characterized in that the contacts ( 9 , 10 ) as so-called. Kelvin contacts on the movably mounted side ( 9 d) are extended. 5. Contacting device according to claim 1 to 4, characterized in that the contacts ( 9 , 10 ) are cranked outwards towards the wall. 6. Contacting device according to claim 1 to 5, characterized in that the contacts ( 9 , 10 ) to the ejector ( 7 ) or to the inserted component ( 2 ) are biased. 7. Contacting device according to claim 6, characterized in that the bias is caused by bending at the point ( 9 c) in the vicinity of the implementation through the base plate ( 3 ). 8. Contacting device according to claim 1, characterized in that the ejector ( 7 ) covers the insertion opening for the feed channel ( 6 a) flush with the edge. 9. Contacting device according to claim 1 to 8, characterized in that the ejector ( 7 ) floating on ejector springs ( 8 ) is mounted. 10. Contacting device according to claim 1 to 9, characterized in that the ejector ( 7 ) through the contacts ( 9 , 10 ) is guided laterally. 11. Contacting device according to claim 1 to 10, characterized in that the ejector ( 7 ) with arms ( 7 a) since Lich in the socket body ( 4 ). 12. Contacting device according to claim 1 to 11, characterized in that the ejector springs ( 8 a) are moved outwards to the boom ( 7 a). 13. Contacting device according to claim 1 to 12, characterized in that the base plate ( 3 ) between the contacting side and the connection side is dust and gas-tight. 14. Contacting device according to claim 1 to 13, characterized in that the contacts ( 9 , 10 ) laterally offset through the base plate ( 3 ) are guided.