DE202014100714U1 - Tester - Google Patents

Abstract

Test device (2) for spring contact pins (4) comprising a holder (6) for a spring contact pin (4) to be tested, an actuator unit (8) for an automated movement of the spring contact pin (4) to be tested, a mating contact (18) for the test to be tested Spring contact pin (4) and comprising a measuring unit (14) and a control and evaluation unit (22) for determining a test value, wherein the control and evaluation unit (22) for automated performance of a test of the spring contact pin to be tested (4) is formed.

Description

The invention relates to a test device for spring contact pins comprising a holder for a spring contact pin to be tested.

Test or test units that are designed to test electronic components, such as populated printed circuit boards, often have so-called spring contact pins, which are also referred to as spring contacts or spring pins on. Such spring contact pins typically comprise three components, namely a so-called guide tube, also called pin sleeve or housing, a piston mounted in the guide tube and displaceable against the guide tube and a spring acting between the guide tube and the piston.

To test an electronic module, for example, in the context of the manufacturing process of corresponding electronic modules, then usually several spring contact pins are placed simultaneously on an electronic module to be tested so that contact is made by contacting a contact between the spring contact pins and the electronic assembly to be tested, typically by each Contacting, so by each spring contact pin, an electrical circuit for a measurement process for testing the electronic assembly is closed. After a corresponding measurement process, the contacts formed in this way are dissolved again and the corresponding spring contact pins are led away from the tested electronic module.

With the help of such test or test units, there is also a quality check of high-quality electronic assemblies, which is why the qualitative requirements are typically relatively high, especially to the corresponding spring contact pins. Among other things, it is essential that the springs of the spring contact pins have a long life expectancy and ensure in this time the most constant spring force with which the pistons of the spring contact pins are pressed against them in a test of an electronic module.

Proceeding from this, the present invention seeks to provide a tester for spring contact pins.

This object is achieved by a test device with the features of claim 1. Preferred developments are contained in the dependent claims.

A corresponding test device is designed to be able to test with this spring contact pins, and for this purpose comprises a holder for at least one spring contact pin to be tested, an actuator unit for automated relative movement of the at least one spring contact pin and a counter contact for at least one spring contact pin to be tested. Moreover, the test apparatus comprises a measuring unit and a control and evaluation unit for determining a test value, wherein the control and evaluation unit is designed for the automated performance of a test of the at least one spring contact pin to be tested.

A test value determined by means of this test device serves to characterize the tested spring contact pin and, accordingly, a corresponding test value describes the properties of the spring contact pin. By testing spring contact pins by means of the test device, it is thus possible to determine whether or not their properties correspond to the desired or required properties. Carrying out the test is thereby automated, which on the one hand reduces the workload for a corresponding test of spring contact pins and, on the other hand, ensures that the test of the spring contact pins is carried out correctly. Faulty test results due to operating errors, such as occur frequently in manual test procedures are thus excluded in principle.

Such a test device is expediently used for quality assurance in the production of spring contact pins. Alternatively, by means of the test device, a test of spring contact pins, which are already in use, so are installed, for example, in a test unit, which is used for testing electronic assemblies. In this case, it is then determined by means of the test device, whether the spring contact pins of the test unit are still in order and can be used or whether they must be replaced by new spring contact pins.

For a test, a spring contact pin to be tested is inserted into the holder provided for this purpose, and subsequently the automated performance of the test, ie a test procedure, is started, for example by an operator pressing a start key. As a result, the spring contact pin located in the holder is then moved by means of the actuator unit in the direction of the counter contact until the spring contact pin to be tested touches the mating contact and the piston of the spring contact pin to be tested is displaced as a result of contact with the mating contact against the guide tube. If the piston of the spring contact pin to be tested is then displaced by a predetermined distance, for example 1 to 2 mm, against the guide tube, then the actuator unit is controlled in such a way that the movement is stopped and by means of the measuring unit a measured value is generated which is either used for the determination of the test value or serves directly as a test value. Subsequently, by means of the actuator unit, a movement of the spring contact pin to be tested from the mating contact and thus a movement back to the starting position, whereby the testing process is completed. The tested spring contact pin is then removed from the holder and, if necessary, another spring contact pin to be tested is inserted into the holder for a new test procedure.

Preferably, in the context of a test procedure, a contact force value for the contact force between the spring contact pin to be tested and the mating contact is determined as the test value. In this case, the measuring unit is expediently designed as a force sensor or force transducer and comprises, for example, a piezoceramic element for this purpose.

Alternatively, a value for the spring constant of the spring of the spring contact pin is determined as the test value, wherein also in this case expediently the measuring unit is designed as a force sensor. The determination of the spring constant or spring rate then takes place in the control and evaluation unit by applying an evaluation algorithm to the measured value generated by the measuring unit.

In an advantageous development, the determined test value is compared by means of the control and evaluation unit within the scope of the test procedure with a stored reference value or reference value range. If the test value deviates from the reference value or if the test value lies outside the test value range, a warning signal is output by the control and evaluation unit. This alert signal then gives an operator to understand that the properties of the tested spring pin do not meet the specifications.

Depending on the design variant of the test apparatus, the indication signal is an acoustic signal or else an optical signal, the output of the indication signal being preferred via an optical display. As an alternative to a simple output of an indication signal, according to an embodiment variant of the testing device, it is provided to reproduce the determined test value via an optical display, that is to say, for example, to display a value for the determined contact force.

It is advantageous, furthermore, if the test apparatus is designed for a parallel or simultaneous testing of a plurality of spring contact pins to be tested, in which case a parallel test of a plurality of spring contact pins preferably takes place such that an individual test value is determined for each spring contact pin. In this way, several spring contact pins can be checked simultaneously, which further reduces the effort required to test spring contact pins, and at the same time an individual test value is determined for each spring contact pin so that individual faulty spring contact pins can be easily filtered out and sorted out.

In particular, if the test device is designed for a parallel test of several spring contact pins, it is also useful if the holder is designed in the manner of a plug-in board, so that the test spring pins for testing in corresponding receptacles in the plug-in, ie in the holder, simply plugged become. The receptacles for the spring contact pins are arranged in a matrix-like manner distributed over the plug-in plate according to one embodiment, so that they form, for example, a rectangular grid. Preferably, an optical display adapted thereto is then also provided, in which a number of light-emitting diodes corresponding to the number of receptacles are arranged in a comparable pattern.

According to a further preferred embodiment of the test device according to the mating contact is designed as a female connector. In this case, the holder is then preferably designed such that when a contact between a spring contact pin to be tested and the female connector, a circuit is closed, which serves as a control circuit. Such an embodiment of the test device is for example advantageous if differently designed and in particular different length spring contact pins to be tested with the tester. In this case, then the spring contact pins for a test by means of the actuator unit in the direction of the female connector, so the mating contact, proceed until a contact is made between the spring contact pins to be tested and the female connector. The length of the trajectory is initially unknown and depends on the length of the spring contact pins to be tested. By contacting, however, the control circuit is closed and in this way it is detected that the spring contact pins have reached the desired position.

Preferably, the actuator unit is designed as a pneumatic device with a cylinder and with a movable punch. Corresponding pneumatic devices can be realized without major technical effort and are also considered to be quite robust and durable.

A test device presented here is also integrated in particular in a production plant or production line and thus designed for a kind of "online" test. With the help of a corresponding test device, for example, individual spring contact pins are then randomly tested from a batch or else all spring contact pins are subjected to a test during production.

According to an alternative, the test apparatus is integrated into a test unit which is designed for testing electronic assemblies, that is to say, for example, for testing populated semiconductor boards, and has a number of spring contact pins for this purpose. This means that the test unit, with the help of which electronic assemblies are tested, additionally comprises a test device with the aid of which a type of self-diagnosis can be performed, at least as far as the proper functioning of the spring contact pins of the test unit is concerned. In this case, it is generally not necessary to install all components which are necessary for the realization of one of the test devices presented here as additional assemblies in the test unit. It should be considered that a corresponding test unit usually already has assemblies and a holder, an actuator unit and / or a central control and evaluation, since these are usually required anyway for testing electronic assemblies. In order to realize an integrated test device in the test unit, it therefore only has to be supplemented by the subassemblies that are not already present, that is, in particular, by the measuring unit. In this case, the additionally added assemblies are preferably designed in the manner of a module or adapter, so that, for example, also test units that are already in use, can be retrofitted. A corresponding module-like or adapter-like configuration also offers the possibility of always inserting such a module or such an adapter into a test unit only when required, in which case a corresponding module or a corresponding adapter can be used for a plurality of test units.

An embodiment of the invention will be explained in more detail with reference to a schematic drawing. Show:

1 in a combined representation of front view and block diagram representation of a test device for spring contact pins.

An example described below and in 1 sketched test device 2 is used to test spring contact pins 4 and has a holder for this purpose 6 on, which is designed in the manner of a plug-in plate with twenty arranged in a rectangular grid recordings. In each of these shots can be a spring contact pin 4 plug in for a test and accordingly the test device 2 Designed to hold up to twenty spring contact pins 4 to be tested simultaneously.

Next includes the tester 2 a trained as a pneumatic device actuator 8th with a pneumatic cylinder 10 and with a movable ram or stamp 12 , On this stamp 12 is a designed in the manner of a force sensor measuring unit 14 positioned on which the spring contact pins to be tested 4 rest with one end.

On the opposite side is beyond a Prüfmodulkopf 16 arranged so that the spring contact pins to be tested 4 after plugging into the holder 6 between the measuring unit 14 and the test module head 16 are placed. At the test module head 16 can be differently designed socket connector 18 attach to the differently designed spring contact pins 4 are adjusted. As a result, can be by means of the tester 2 different spring contact pins 4 check, each with the appropriate socket connector 18 for testing corresponding spring contact pins 4 at the test module head 16 to attach.

For a test procedure is now the bracket 6 the tester 2 with a number ≤ 20 spring contact pins 4 equipped and subsequently the test procedure by the operation of a control element 20 , like a start button, on a control and evaluation unit 22 started. The control and evaluation unit 22 subsequently performs the test in the holder 6 inserted spring contact pins 4 , where first the stamp 12 from the pneumatic cylinder 10 is extended. This will cause the on the stamp 12 seated measuring unit 14 together with the one-sided on the measuring unit 14 resting spring contact pins 4 and the holder 6 in the direction of the test module head 16 and accordingly in the direction of the female connector 18 method. Here is the holder 6 on the edge with the help of two rail-like guide elements 24 guided to ensure a linear movement as possible. After a certain travel distance reach the spring contact pins 4 with her the measuring unit 14 opposite end of the socket connector 18 and between the spring contact pins 4 and the female connector 18 a detachable contact connection is formed.

Through this contact connection, a control circuit is closed and consequently we the actuator unit 8th stopped. The following is by means of the measuring unit 14 , which is designed as a force sensor, the contact force between each spring contact pin 4 and the corresponding mating contact in the socket connector 18 metrologically recorded and the thus determined contact force values for the spring contact pins 4 are then in the control and evaluation 22 evaluated.

In this case, it is determined whether the respective contact force value lies within a reference value range which is stored in a memory. If the metrologically recorded contact force value lies within this reference value range, then the corresponding spring contact pin complies 4 the specifications and can be used accordingly. Is the metrologically detected contact force value of a spring contact pin 4 however, outside the reference range, so does the corresponding spring contact pin 4 undesirable properties and as a result is from the control and evaluation unit 22 an indication signal is output, which via a visual display 26 is shown.

The optical display 26 is composed of twenty individual light-emitting diodes, which are arranged in a similar manner as the spring contact pins 4 in the holder 6 , Each spring contact pin 4 Thus, a light emitting diode is assigned so that it is an operator of the tester 2 It is possible to determine which of the tested spring contact pins 4 has undesirable properties or is faulty. In the exemplary embodiment, the optical display is now 26 configured such that for each recording in the holder 6 in which a spring contact pin 4 a light emitting diode is lit, whereas the light emitting diodes associated with unoccupied shots do not light up.

Upon completion of a test procedure, the stamp becomes 12 moved back to its original position, in which case also the holder 6 with the spring contact pins 4 be moved back to their original position. At the same time, the optical display 26 shown, whether and which spring contact pins 4 do not meet the requirements by the associated LEDs no longer light permanently, but are controlled clocked instead, so flashing. The spring contact pins 4 can then be removed from the holder 6 remove and the test device 2 is by a renewed actuation of the control element 20 returned to their original state and thus made ready for a new inspection.

The invention is not limited to the embodiment described above. Rather, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, all the individual features described in connection with the exemplary embodiment can also be combined with each other in other ways, without departing from the subject matter of the invention.

LIST OF REFERENCE NUMBERS

2

Tester

4

Spring contact pin

6

bracket

8th

actuator

10

Pneumatic cylinder

12

stamp

14

measuring unit

16

Prüfmodulkopf

18

female connector

20

operating element

22

Control and evaluation unit

24

guide element

26

Optical display

Claims (12)

Tester ( 2 ) for spring contact pins ( 4 ) comprising a holder ( 6 ) for a spring contact pin to be tested ( 4 ), an actuator unit ( 8th ) for an automated movement of the spring contact pin to be tested ( 4 ), a counter contact ( 18 ) for the spring contact pin to be tested ( 4 ) and comprising a measuring unit ( 14 ) and a control and evaluation unit ( 22 ) for determining a test value, wherein the control and evaluation unit ( 22 ) for automatically carrying out a test of the spring contact pin to be tested ( 4 ) is trained. Tester ( 2 ) according to claim 1, wherein as test value a contact force value for the contact force between the spring contact pin to be tested ( 4 ) and the counter contact ( 18 ) is determined. Tester ( 2 ) according to claim 1, wherein as a test value, a value for the spring constant of the spring contact pin ( 4 ) is determined. Tester ( 2 ) according to one of claims 1 to 3, wherein by means of the control and evaluation unit ( 22 ) the test value is compared with a reference value or reference value range and wherein the control and evaluation unit ( 22 ) emits a warning signal in the event of a deviation of the test value from the reference value or from the reference value range. Tester ( 2 ) according to claim 4, wherein the indication signal is provided by means of an optical display ( 26 ) is output. Tester ( 2 ) according to one of claims 1 to 5, wherein this for parallel testing of a plurality of spring contact pins ( 4 ) is trained. Tester ( 2 ) according to claim 6, wherein this is for parallel testing of a plurality of spring contact pins ( 4 ) is designed such that for each spring contact pin ( 4 ) an individual test value is determined. Tester ( 2 ) according to one of claims 1 to 7, wherein the holder ( 6 ) is designed in the manner of a plug-in plate. Tester ( 2 ) according to one of claims 1 to 8, wherein the mating contact ( 18 ) as a female connector ( 18 ) is trained. Tester ( 2 ) according to one of claims 1 to 9, wherein the actuator unit ( 8th ) as a pneumatic device with a cylinder ( 10 ) and a movable stamp ( 12 ) is trained. Tester ( 2 ) according to one of claims 1 to 10, wherein this is integrated into a production plant. Tester ( 2 ) according to one of claims 1 to 10, wherein this is integrated into a test unit, which for testing electronic assemblies using the spring contact pins ( 4 ) is trained.

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