EP0629869B1

EP0629869B1 - Test apparatus

Info

Publication number: EP0629869B1
Application number: EP19940304098
Authority: EP
Inventors: John Woodrow Shere; Neil Graham Hemingway
Original assignee: UH VENTURES Ltd; Matra Bae Dynamics UK Ltd
Current assignee: UH VENTURES LTD.; Matra Bae Dynamics UK Ltd
Priority date: 1993-06-12
Filing date: 1994-06-07
Publication date: 1999-03-03
Anticipated expiration: 2014-06-07
Also published as: GB2278975A; GB9312162D0; DE69416728T2; DE69416728D1; EP0629869A1

Description

This invention relates to apparatus and methods suitable for the testing of electronic components which are mounted on printed circuit boards.
WO-A-89/12379 describes a system for detecting free particles in component housings assembled on a printed circuit board. The board is secured to a vibrating table and a piezoelectric sensor, placed on individual integrated circuit packages listens for sound impacts generated by free particles trapped within. Vibration levels of the table can be monitored and controlled by means of an accelerometer mounted thereon. However, the system described therein fails to provide a means for applying vibration locally to an integrated circuit package and also fails to provide a means for measuring the local vibration levels that the package sustains during a test procedure.
To ensure that an item of electronics equipment is reliable in the field it is standard practice to condition equipment to eliminate early failures. This process is known by a number of terms including:- Environmental Stress Screening, In-Process Conditioning, and the related term Burn-In.
These processes involve placing equipment in environmental chambers and subjecting them to repeated cycles of temperature extremes (typical -30°C +50°C) plus vibration over a total period of 4 to 40 hours typical. Units are stimulated by external equipment such as a vibrating platform, for example, and critical signals are monitored by computer to record any failures. All equipment that survives such tests can be statistically proven to be more reliable.
With a large throughput of such equipment there are bound to be failures that require diagnosis. If something breaks or shows the same problem under ambient conditions this is not too difficult to resolve. If it sometimes only fails at a temperature extreme or with vibration applied this is a difficult problem to diagnose.
Whereas there are a number of items which can be used to diagnose thermally induced problems e.g. heat guns, freezer sprays, this invention aims to provide a method and apparatus for diagnosis of vibration related failures. Furthermore the invention aims to provide a controlled, portable, local source of vibration.
Hence this invention consists of an apparatus for testing the performance of electronic components under vibratory conditions, the apparatus including a probe body having a probe head for coupling to an electronic component, means for monitoring vibratory levels and charaterised in that the probe body includes means for vibrating the probe head thereby applying a local source of vibration to the electronic component, at a discrete point on its structure.
The means for vibrating the probe head could comprise a high-power electro-magnetic transducer.
The means for monitoring vibrations could comprise a miniature piezo-electric accelerometer which could be fixed to the probe body. Velocity, force or displacement transducers may be preferred alternatives for some applications. The vibration monitor could be incorporated in a feedback loop for controlling the operating of the vibration source.
Instead of, or in addition to a vibration level monitor fixed to the probe body, a "roving" sensor moveable to various locations around a printed circuit board could be used to monitor the actual vibration levels of the board and its components. Again, this roving sensor could be used in a feedback loop to control the vibration source. The sensor could be an accelerometer or velocity or displacement transducer as appropriate.
The output from either fixed or roving accelerometer could be integrated electronically to provide velocity and displacement levels.
The probe body and probe head could be incorporated into a pistol-grip, hand-held device, for example, which would allow the direct excitation of standard electronic packages such as Dual in line, TO5 and surface mount devices. This would allow typical faults occurring only during vibration to be reproduced or diagnosed outside the conventional test chamber.
Some embodiments of the invention will now be described, by way of example only, with reference to the drawings of which;
Figure 1 is a schematic view of vibration diagnosis equipment in accordance with the invention, and
Figure 2 is a cross-sectional view of a vibrating probe.
In Figure 1 a probe 1 receives an electrical signal generated by either a sinusoidal frequency source 2 or a noise source 3 (of variable bandwidth). The signal reaching the probe 1 is controlled by an on/off switch 4 and an amplifier 5 of variable gain. The probe 1 incorporates an electro-magnetic vibrator 6 and a first miniature piezoelectric accelerometer 7 and is shown in greater detail in Figure 2.
In Figure 2 the probe 1 comprises an outer casing 8 which houses a magnet 9 and a moving coil assembly 10. The moving coil assembly 10 is attached to a vibration plate 11 on which is mounted a dome-shaped probe head 12 made of plastics and the miniature piezoelectric accelerometer 7.
Returning to Figure 1, the output from the first accelerometer 7 is fed to a charge amplifier 13 whose output is connected to a voltmeter 14 and, if desired, to a spectrum analyser (not shown). An output from the voltmeter 14 is used by a comparator circuit 15 to control the gain of the amplifier 5.
A second miniature piezoelectric accelerometer 16 (remote from the probe 1) has its output connected to a second charge amplifier 17. The output of this amplifier 17 is connected to a second voltmeter 18 and if desired to a spectrum analyser (not shown).
The level of vibration applied to the probe 1, its frequency and its duration are all recorded by a recorder 19 which receives inputs from a timer circuit 20 (connected to the on/off switch 4), a frequency monitor 21 (associated with the sources 3 and 4) and the voltmeter 14.
In operation, the probe head 12 is held either by hand or by a clamping arrangement in contact with an integrated circuit which is mounted on the printed circuit board under test. The excitation frequency desired is set using the appropriate controls provided on the sources 2 and 3. The second "roving" accelerometer is fixed to a point of interest on the board with a thin layer of beeswax. Closing of the switch 4 will than activate the electro-magnetic vibrator 6, the vibrations of the vibration plate 11 being coupled to the integrated circuit via the probe head 12.
The vibrations of the plate 11 are constantly monitored by the first accelerometer 7 which produces a charge proportional to the acceleration applied thereto. The accelerometer's output is conditioned by the charge amplifier which produces a measurable voltage at its output. The rms. level of this voltage, proportional to the acceleration detected by the accelerometer 7 is measured by the voltmeter which can be provided with means for converting the voltage value to units of acceleration. This latter information can be displayed to the operator and is also fed to the recorder 19.
An output from the voltmeter 14 is used, in a feedback loop, to control the gain of the amplifier 5 and therefore the vibration level of the probe head 12. If the measured acceleration rises above a pre-set level, for example, then the comparator circuit 15 reduces the gain of the amplifier 5 accordingly. In this way, the probe head 12 and thus the component under test can be protected from overload.
Typical frequencies and acceleration levels applied range from 10Hz to 2kHz and 2g(rms) to 5g (rms) respectively.
The acceleration level, frequency and length of time for which excitation persists are continually recorded by the recorder 19 using the inputs from the timed circuit 20, frequency monitor 21 and voltmeter 14.
During excitation the electrical functions of the printed circuit board are constantly monitored.
Also, during excitation, the roving, second accelerometer detects acceleration at the pre-chosen point of interest. In a similar fashion to the acceleration monitoring operation at the probe head, a 'g' level can be displayed by the second voltmeter 18.
The above operations can be repeated at different locations around the board under test until its design criteria have been reached or it fails electrically. The amount of vibration to which the board has been subjected can be ascertained by interrogating the recorder 19. Thus the operator can ensure that the board has not exceeded its design requirements and is therefore fit for sale if no electrical faults have been found during testing.
The recorder 19 also tells the operator the conditions under which any failure occurred. When an electrical failure does occur, then the diagnostic equipment is removed and further solely electrical tests are carried out on each integrated circuit or each printed track if necessary, to find out which component or soldered joint, for example has actually failed.
The arrangement of Figure 1 could also be used for modal analysis of board vibrations by examining the output of the roving accelerometer with a spectrum analyser and applying an impulse to the board through the probe head.

Claims

Apparatus for testing the performance of electronic components under vibratory conditions, the apparatus including a probe body (1) having a probe head (12) for coupling to an electronic component, means (7, 16) for monitoring vibratory levels and characterised in that the probe body (1) includes means (6) for vibrating the probe head (12) thereby applying a local source of vibration to the electronic component, at a discrete point on its structure.
Test apparatus according to claim 1 in which the means (7, 16) for monitoring the vibratory levels include a sensor (7) connected to the probe body (1).
Test apparatus according to claim 1 in which the means (7, 16) for monitoring the vibratory levels include a sensor (16) remote from the probe head (12).
Test apparatus according to any preceding claim in which the means (7, 16) for monitoring the vibratory levels comprises an accelerometer.
Test apparatus according to any preceding claim in which the means (6) for vibrating the probe head comprises an electro-magnetic transducer (9, 10, 11).
Test apparatus according to any preceding claim in which the means (6) for vibrating the probe head and the means (7, 16) for monitoring the vibratory levels form part of a feed-back loop.