JP3366239B2 - Probe card cleaning equipment - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for cleaning a probe card, and more particularly, to a method for cleaning a plurality of semiconductor integrated circuit elements formed on a semiconductor wafer. The present invention relates to a cleaning apparatus for cleaning the surface of a probe card for performing burn-in at a time. 2. Description of the Related Art Conventionally, in a semiconductor integrated circuit device, after a semiconductor integrated circuit element and a lead frame are electrically connected by bonding wires, the semiconductor integrated circuit element and a lead of the lead frame are made of resin or ceramic. Is supplied in a state sealed by the, and is mounted on a printed circuit board. However, in response to demands for downsizing and cost reduction of electronic equipment, a method of mounting a semiconductor integrated circuit device on a circuit board in a bare chip state as cut out from a semiconductor wafer has been developed, and the quality has been assured. It is desired to supply bare chips at a low price. In order to guarantee the quality of bare chips, it is necessary to perform burn-in on the electrical characteristics of semiconductor integrated circuit elements in a wafer state. Therefore, for example, NIKKEI MICRODEVICES 19
As described in the July 1997 issue, a wafer tray holding a semiconductor wafer on which semiconductor integrated circuit elements are formed, and a semiconductor tray provided to face the semiconductor wafer held on the wafer tray, A wafer cassette including a probe card having a bump connected to a test terminal of an integrated circuit element and an annular seal member provided between the wafer tray and the probe card and forming a sealed space together with the wafer tray and the probe card is provided. Proposed. Hereinafter, a wafer burn-in method using the wafer cassette will be described with reference to FIGS. 2 and 3. FIG. 2 shows a sectional structure of the wafer cassette, and FIG. 3 shows a partially enlarged sectional structure of FIG. As shown in FIG. 2, a wafer tray 11 holding a semiconductor wafer 10 and a wiring board 13 holding a probe card 12 are provided so as to face each other, and an annular seal is provided on a peripheral portion of the wafer tray 11. Lumber 14
When the wafer tray 11 and the probe card 12 are brought close to each other, a sealed space 15 is formed by the wafer tray 11, the probe card 12, and the seal member 14. As shown in FIG. 3, each semiconductor integrated circuit element formed on a semiconductor wafer 10 is
have. As shown in FIGS. 2 and 3, bumps 17 are provided at portions of the probe card 12 corresponding to the test electrodes 16 of the semiconductor integrated circuit elements on the semiconductor wafer 10, and the probe card 12 Is held by a rigid ring 18. As shown in FIG. 3, one end of the wiring board 13 is connected to an inspection device (not shown) for supplying an inspection voltage such as a power supply voltage, a ground voltage or a signal voltage.
5 and an anisotropic conductive rubber 26 for electrically connecting the other end of the multilayer wiring 25 to the bump 17 of the probe card 12. In the state shown in FIG. 2, when the sealed space 15 formed by the wafer tray 11, the probe card 12, and the seal member 14 is decompressed by a decompression means (not shown), the wafer tray 11 and the probe card 12 come closer to each other, As shown in FIG. 3, the inspection electrode 16 of the semiconductor integrated circuit element on the semiconductor wafer 10 and the probe card 1
The two bumps 17 are electrically connected. Thereafter, the inspection apparatus applies an inspection voltage to each semiconductor integrated circuit element on the semiconductor wafer 10 or inputs an output signal from each semiconductor integrated circuit element to the inspection apparatus, and the inspection apparatus Evaluate the electrical characteristics of the device. However, the conventional wafer burn-in system has the following problems. That is, in wafer burn-in,
In order to perform temperature acceleration, the semiconductor wafer 10 is, for example, 125
It is necessary to raise the temperature to ° C. Therefore, the wafer tray 11
The temperature of the semiconductor wafer 10 is raised by a heater built in the semiconductor wafer 10, or the temperature of the semiconductor wafer 10 itself is raised by the heat accompanying the operation of each semiconductor integrated circuit element on the semiconductor wafer 10. Therefore, when the semiconductor wafer 10 thermally expands, the inspection electrodes 16 of the semiconductor integrated circuit elements on the semiconductor wafer 10 and the bumps 17 of the probe card 12 are in sliding contact with each other.
In addition, a foreign substance made of a metal powder such as aluminum which forms the inspection electrode 16 adheres. Further, when wafer burn-in is repeatedly performed on a plurality of semiconductor wafers 10 using the same probe card 12, the amount of foreign matters made of metal powder such as aluminum adhering to the bumps 17 of the probe card 12 increases. The metal powder such as aluminum has a natural oxide film formed on the surface due to oxygen in the air, and has a reduced conductivity. Therefore, when foreign matter adheres to the bumps 17 of the probe card 12, the semiconductor wafer 10 Upper inspection electrode 16
And the bumps 17 of the probe card 12 cause a contact failure, and the wafer burn-in is not performed well. In view of the foregoing, it is an object of the present invention to provide a probe card cleaning apparatus capable of removing foreign matter such as metal powder attached to bumps of a probe card. In order to achieve the above object, a probe card cleaning apparatus according to the present invention is provided with a plurality of inspection electrodes of a plurality of semiconductor integrated circuit elements formed on a semiconductor wafer. It has a plurality of bumps that are in contact with each other, supplies a test voltage to each test electrode of a plurality of semiconductor integrated circuit devices via each bump, and burns in a batch on the plurality of semiconductor integrated circuit devices in a wafer state. A brushing means for rubbing foreign substances adhered to the surface of the bumps of the probe card, which is intended for a probe card cleaning device for performing
By spraying the ionized cleaning liquid onto the surface of the probe card where the bumps are formed, the brushing means is used to wash away foreign substances scraped off from the bump surface, and the probe card surface is a conductive liquid comprising the ionized cleaning liquid. A cleaning liquid supply means for forming a film to remove static electricity generated on the surface of the bump; and a conductive liquid formed on the surface of the probe card by blowing gas on the surface of the probe card on which the bump is formed. Drying means for drying the surface of the probe card by evaporating the film. According to the probe card cleaning apparatus of the present invention, since the brushing means for rubbing foreign substances adhered to the surface of the bumps of the probe card is provided, the bumps of the probe card can be used to inspect semiconductor integrated circuit elements on the semiconductor wafer. Foreign matter such as metal powder adhered to the surface of the bump when slidingly contacting the electrode for use is scraped off by brushing means. In addition, a cleaning liquid supply for washing away foreign substances scraped off from the surface of the bump and forming a conductive liquid film of an ionized cleaning liquid on the surface of the probe card to remove static electricity generated on the surface of the bump. Means, the foreign matter scraped off from the surface of the bump is removed from the surface of the probe card, and the static electricity generated on the surface of the bump when the bump of the probe card is rubbed by the brushing means is electrically conductive. Diffuses inside the liquid film and disappears from the surface of the bump. Further, since the drying means for evaporating the conductive liquid film formed on the surface of the probe card to dry the surface of the probe card is provided, the liquid film formed by the cleaning liquid supply means can be quickly removed. Evaporation can dry the surface of the probe card. In the probe card of the present invention, it is preferable that the drying means blows ionized gas onto the surface of the probe card on which the bumps are formed. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A probe card cleaning apparatus according to an embodiment of the present invention will be described below with reference to FIG. FIG. 1 schematically shows a probe card to be cleaned and a probe card cleaning apparatus according to an embodiment of the present invention. As shown in FIG. Bumps 17 are formed on the semiconductor wafer 12 so as to correspond to the test electrodes of each semiconductor integrated circuit element on the semiconductor wafer. The wiring board 13 holding the probe card 12 has a multilayer wiring 25 and an anisotropic conductive rubber. 26 are provided. In this embodiment, the probe card is held so as to move from left to right in FIG. The apparatus for cleaning a probe card includes a main body 3 of the apparatus.
The brush 31 is provided rotatably at 0 and rubs off foreign substances attached to the bumps 17 of the probe card 12, and the cleaning liquid provided on the apparatus body 30 and ionized on the surface of the probe card 12 (for example, ionized cleaning liquid) water)
A cleaning liquid injection nozzle 32 that sprays the nozzles in the form of mist and a gas injection nozzle 33 that is provided in the apparatus main body 30 and that sprays ionized gas onto the surface of the probe card 12 are provided. The material of the brush 31 is not particularly limited. However, when the brush 31 rubs against the probe card 12 made of polyimide and the bumps 17 formed on the probe card 12,
It is preferable that the probe card 12 and the bump 17 have such a property that static electricity is unlikely to be generated, and that the probe card 12 and the bump 17 have such a rigidity that a foreign substance such as a metal powder attached to the surface of the bump 17 can be scraped off. The cleaning liquid storage tank 34 stores an ionized cleaning liquid obtained by, for example, dissolving carbon dioxide gas or the like in water. The ionized cleaning liquid is supplied by a pumping means such as a pump (not shown). After being supplied to the cleaning liquid injection nozzle 32, it is sprayed onto the surface of the probe card 12 from the injection port of the cleaning liquid injection nozzle 32. On the other hand, the gas storage tank 35 stores an ionized gas obtained by applying a high-frequency power to a gas such as air or nitrogen gas, and the ionized gas is not shown. After being supplied to the gas ejection nozzle 33 by a pumping means such as a pump, the gas is sprayed from the ejection port of the gas ejection nozzle 33 onto the surface of the probe card 12. Hereinafter, a cleaning method performed by using the probe card cleaning apparatus according to one embodiment of the present invention will be described. First, the apparatus main body 30 is brought close to the probe card 12 to such an extent that the tip of the brush 31 contacts the surface of the bump 17 of the probe card 12. Next, the probe card 12 is moved from the left side to the right side in FIG. 1 while rotating the brush 31 and spraying the ionized cleaning liquid from the cleaning liquid injection nozzle 32, so that the probe card 12 and the apparatus main body 30 are connected to each other. Is relatively moved in the left-right direction. In this manner, foreign matter such as metal powder adhering to the surface of the bump 17 of the probe card 12 is scraped off by the brush 31. Then, in order to spray the ionized cleaning liquid from the cleaning liquid spray nozzle 32 onto the surface of the probe card 12, the foreign matter scraped off from the surface of the bump 17 by the brush 31 is washed away by the cleaning liquid and removed from the surface of the probe card 12. . When the bump 17 and the brush 31 rub against each other, static electricity is generated on the surface of the bump 17. However, since the ionized cleaning liquid is sprayed from the cleaning liquid jet nozzle 32 onto the surface of the probe card 12, the bump 17 The static electricity generated on the surface is diffused and removed inside the conductive liquid film. Instead of rotating the brush 31 and simultaneously spraying the ionized cleaning liquid from the cleaning liquid spray nozzle 32, the brush 31 is rotated to remove foreign matter on the surface of the bump 17 and then ionized from the cleaning liquid spray nozzle 32. A cleaning solution is sprayed on the surface of the probe card 12,
The static electricity generated on the surface of the bump 17 may be removed. Next, the probe card 12 and the apparatus body 30
By further moving ionized gas onto the surface of the probe card 12 from the gas injection nozzle 33 while further moving the substrate, the conductive liquid film formed on the surface of the probe card 12 is evaporated, whereby the probe card 12 Dry the surface. In this case, the gas injection nozzle 3
Since the ionized gas is blown onto the surface of the probe card 12 from 3, it is possible to avoid a situation where static electricity is generated again on the surface of the bump 17 when the surface of the probe card 12 is dried. According to the probe card cleaning apparatus of the present invention, foreign matter such as metal powder attached to the surface of the bumps of the probe card is scraped off by the brushing means, and then the probe card is supplied from the cleaning liquid supply means to the probe card. It is removed from the surface of the probe card by being washed away by the cleaning liquid sprayed on the surface of the probe card. Further, since the ionized cleaning liquid is sprayed onto the surface of the probe card from the cleaning liquid supply means,
Since the static electricity generated on the surface of the bump is diffused and removed inside the conductive liquid film formed on the surface of the probe card, the static electricity on the surface of the bump is reliably removed. Further, since the drying means for drying the surface of the probe card is provided, even if the surface of the probe card becomes wet with the cleaning liquid, it can be dried quickly. In the probe card cleaning apparatus of the present invention, when the drying means blows ionized gas onto the surface of the probed on which the bumps are formed, static electricity reappears on the surface of the bumps when the surface of the probe card is dried. A situation that occurs can be avoided.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic overall view of a probe card cleaning apparatus according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of a wafer cassette provided with a probe card to be cleaned by the probe card cleaning apparatus according to the present invention. FIG. 3 is a partially enlarged sectional view of a wafer cassette provided with a probe card to be cleaned by the probe card cleaning apparatus according to the present invention. DESCRIPTION OF SYMBOLS 10 Semiconductor wafer 11 Wafer tray 12 Probe card 13 Wiring board 14 Seal member 15 Sealed space 16 Inspection electrode 17 Bump 18 Rigid ring 30 Device body 31 Brush 32 Cleaning liquid injection nozzle 33 Gas injection nozzle 34 Cleaning liquid storage tank 35 Gas storage tank

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-4-338662 (JP, A) JP-A-7-161784 (JP, A) JP-A 8-250557 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H01L 21/66 G01R 1/06 G01R 31/28

Claims (1)

(57) [Claim 1] A plurality of semiconductor integrated circuit devices formed on a semiconductor wafer, the plurality of semiconductor integrated circuit devices having a plurality of bumps in contact with the respective test electrodes, and the plurality of bumps being contacted through the respective bumps. A probe card cleaning apparatus for supplying a test voltage to each test electrode of a semiconductor integrated circuit element and performing burn-in on the plurality of semiconductor integrated circuit elements at a time in a wafer state, comprising: A brushing means for scraping foreign matter attached to the surface of the bump of the card; and a foreign matter scraped off from the surface of the bump by the brushing means by spraying an ionized cleaning solution on the surface of the probe card on which the bump is formed. And a conductive liquid film made of an ionized cleaning liquid is formed on the surface of the probe card, A cleaning liquid supply means for removing static electricity Flip to have the on the surface bumps are formed in the probe card by blowing ionized gas, evaporating the conducting liquid film formed on the surface of the probe card And a drying means for drying the surface of the probe card.