EP0387130A1 - Device for marking the crystal orientation and the rectification of a rod - Google Patents

Abstract

Device for marking the crystal orientation and rectifying a bar, comprising: a guide part (30) having a first receptacle (32) capable of receiving said bar (18) and having a plane face (34) intersecting the first receptacle (32) so as to form an orifice (36) of specific width along the first receptacle (32); a fastening means capable of fastening the bar (18) inside the receptacle (32) of the guide part (30). The invention is used for producing marking flats on bars of semiconductor and of monocrystalline material which are intended for the manufacture of wafers. <IMAGE>

Description

The present invention relates to a device for locating the crystal orientation and rectifying a bar. It applies in particular to the production of locating flats on cylindrical bars of semiconductor and monocrystalline material intended for the production of wafers (wafers in English terminology).

A rod is made of monocrystalline semiconductor material (gallium arsenide for example) by known methods of crystal growth. A raw monocrystalline draft bar has two end faces which, once erected, are oriented along defined and known crystal planes (the plans [100] for AsGa, for example).

The bar is then lapped so as to make it cylindrical, the generatrices of the cylinder being perpendicular to the end faces. The cylinder diameter is normalized: it can be 2 inches (5.08 cm) or 3 inches (7.62 cm).

Figure 1 schematically shows an exploded view of a device for preparing the running-in operation.

This device comprises a support 10 for aligning along an axis AA, two end pieces 12. One of the end pieces 12 rests on the support 10 and is centered relative to the axis AA. The translation along AA of the other end piece 12 is free. This translation is guided by a part 14 fixed on one end of the support 10. This part 14 has an orifice crossed by a cylinder 16 on which the end piece 12 is fixed. The axis of revolution of the cylinder 16 coincides with the axis AA. The translation of the cylinder 16 causes the translation of the end piece 12 along the axis AA.

FIG. 2 schematically represents a lapping bar introduced into the device represented in FIG. 1. The end pieces 12 are hot glued, at 50 ° C. for example, using a resin, on the end faces 20, 21 of the bar 18. A pressure is applied (symbolized by an arrow in FIG. 2) to the end pieces 12 by means of the cylinder 16 for a period depending on the nature of the resin. This duration is fixed by the manufacturer.

FIGS. 3A to 3C represent the actual running-in operation.

There is therefore a bar 18 rough drawing but having two end faces 20, 21 flat and oriented (Figure 3A). On these faces 20, 21 are stuck the end pieces 12 along an axis which defines the axis of revolution of the assembly.

FIG. 3B schematically represents the running-in operation. The assembly comprising the bar 18 and the end pieces 12 is placed between the centering points 22 of a lapping machine (not shown in FIG. 3B). Centering is ensured by conical holes 13 made in the end pieces 12 and capable of receiving the centering points 22 of the lapping machine.

The bar 18 is rotated. A grinding wheel 24 is brought into contact with the bar 18. The longitudinal displacement of the grinding wheel 24 allows the desired diameter of the bar 18 to be set.

FIG. 3C schematically represents the bar 18 once the running-in operation has ended. The axis of revolution of the cylindrical bar 18 coincides with the axis of alignment of the end pieces 12.

Once this shaping is completed, two flats are produced along two generatrices of the bar 18. These flats of standard width, 8 mm for one and 16 mm for the other, are arranged in planes perpendicular to each other. In the following description, the flat width of 8 mm is called small flat and the flat width of 16 mm is called large flat. These planes correspond to determined crystalline orientations ([110] for the small flat area of AsGa, for example).

These flats make it possible to identify the crystal orientations of the slices cut from the bar during the operations for producing electronic circuits.

Usually, a rough location of the two generators to be machined is carried out in order to obtain the two flats. This location is made from surface details observable with the naked eye on the raw drawing bar. Markers are inscribed on the end faces 20, 21 of the bar 18, in indelible ink for example.

In known manner, a blank is made of one of the flats according to one of the marks. Then, successive machining operations are carried out, followed by checks on the orientation of the plane of the flat surface by means of X-ray diffraction, so as to obtain the correct width of the flat as well as the correct orientation.

The second flat is produced using the same technique in a plane perpendicular to that of the first flat.

In known manner, the production of the flats is manual: the bar 18 is applied manually on a rotating grinding wheel, the previously identified generator facing the grinding wheel. This way of operating has many drawbacks.

Respect for the crystalline orientation during successive machining forces the operator to numerous X-ray measurements, given the rough precision of the preliminary location and the uncertainty of manual work. Despite numerous back and forth movements between the X-ray measuring machine and the machining station, the precision thus obtained is not satisfactory.

The present invention overcomes these drawbacks; it makes it possible to obtain greater precision over the width of the flats and the crystal orientation during manual machining of the bar while only making a single X-ray diffraction measurement. Thanks to the device recommended by he invention of locating the second flat is easy once the first flat is located.

Specifically, the present invention relates to a device for adjusting the crystal orientation and the rectification of a crystalline bar of cylindrical shape, said bar having a standardized diameter.

This device comprises: a guide piece having a first housing adapted to receive said bar. This first housing has a longitudinal central axis.

The guide piece has a flat face intersecting the first housing so as to provide an opening of determined width along the first housing.

The device according to the invention further comprises a fixing means capable of fixing the bar inside the housing of the guide piece.

According to a particular embodiment, said bar being of cylindrical shape and having a standardized diameter, the first housing is cylindrical of revolution around the central axis. The diameter of the first housing is then substantially equal to but greater than the standard diameter.

According to a preferred embodiment, the fixing means consists of:
- a bar arranged in a second housing made in the guide piece and opening onto the first housing,
- At least one clamping screw exerting pressure on said bar, passing through a threaded orifice made for this purpose in the guide piece.

This bar possibly has a concave face. In this way, for a cylindrical bar, the concave face is able to match the cylindrical shape of the bar.

The device further comprises means for rotating said bar around the central axis of the first housing of the guide piece.

Preferably, these means for rotating said bar comprise:
a hollow plate rotating around an axis of revolution, this plate being supported by a hollow body able to be fixed to one end of the guide piece,
- a connecting piece secured to the turntable,
a centering end piece capable of being fixed to an end face of the bar, a raised end of the connecting piece being able to fit into a recess in the end piece so as to center the bar inside from the first housing, this end piece being secured to the connecting piece by a fixing means so that a rotation of the turntable causes a rotation of the bar, this end piece having a size such that once introduced into the guide piece, the end piece has no part projecting from the opening of the first housing.

The bar is inserted into the first housing of the guide piece. In the case of a cylindrical bar, the generator of the bar is marked according to which one wishes to machine a flat.

This location is obtained by X-ray diffraction on the bar. The generator chosen is brought into position in the guide part by rotation of the bar which is integral with the turntable.

Once in position the bar is fixed inside the guide piece by the fixing means.

Machining is carried out manually after dismantling the turntable from the guide piece.

The flat face of the guide piece serves as a reference plane. The part of the bar extending beyond the opening of the first housing is adjusted until the flat face comes flush with the surface of the grinding wheel.

Thanks to this flat face, the crystal orientation as well as the width of the flat are guaranteed with great precision.

The device according to the invention also comprises:
two flanges suitable for being fixed by fixing means at each end of the guide piece and each having a flat face of determined width, and projecting from the guide piece,
positioning means capable of positioning the flat face of each flange parallel to the flat face of the guide piece.

According to one embodiment, the positioning means consist of two pins per flange to be positioned, each pin being able to fit into housings made for this purpose in each flange and in the guide piece.

According to another embodiment, the positioning means consist of a pin per flange to be positioned, this pin being able to fit into housings made for this purpose in each flange and in the guide part, and in relief of the relief flange capable of fitting into the first housing of the guide piece.

Once the bar is oriented thanks to the turntable and fixed in its position, the flanges are put in place and a rectification of the bar is carried out to obtain the flat. The machining is carried out manually, the part of the bar extending beyond the opening of the first housing and projecting beyond the flat faces of the flanges is kept in contact with a grinding wheel until the flat faces of the flanges are flush with the surface of the grinding wheel.

The two flats of desired width and crystalline orientation are thus obtained using a single exposure to X-rays and avoiding the imprecision of successive machining operations.

• - la figure 1, déjà décrite, représente schématiquement une vue en éclaté d'un dispositif permettant de préparer une opération de rodage ;
• - la figure 2, déjà décrite, représente schématiquement une vue de face de ce même dispositif avec un barreau brut de tirage positionné en son intérieur,
• - les figures 3A à 3C, déjà décrites, représentent schématiquement les étapes de mise au diamètre d'un barreau brut de tirage,
• - les figures 4A et 4B représentent schématiquement une vue en éclaté et une coupe transverse d'un dispositif selon l'invention,
• - la figure 5A représente schématiquement une vue en éclaté d'un dispositif selon l'invention utilisé pour réaliser un petit méplat,
• - la figure 5B représente schématiquement une variante de réalisation d'un flasque permettant l'usinage d'un petit méplat,
• - les figures 6A à 6D représentent schématiquement les différentes étapes de la réalisation des méplats sur un barreau,
• - la figure 7 représente schématiquement un barreau une fois les deux méplats réalisés.

In any case, the characteristics and advantages of the invention will appear better after the description which follows, given by way of explanation. and in no way limitative. This description refers to attached drawings in which:

• - Figure 1, already described, schematically shows an exploded view of a device for preparing a running-in operation;
• FIG. 2, already described, schematically represents a front view of this same device with a raw draw bar positioned inside it,
• FIGS. 3A to 3C, already described, schematically represent the steps for setting the diameter of a raw drawing bar,
• FIGS. 4A and 4B schematically represent an exploded view and a cross section of a device according to the invention,
• FIG. 5A schematically represents an exploded view of a device according to the invention used to make a small flat,
• FIG. 5B schematically represents an alternative embodiment of a flange allowing the machining of a small flat,
• FIGS. 6A to 6D schematically represent the different stages of the production of the flats on a bar,
• - Figure 7 shows schematically a bar once the two flats made.

FIG. 4A schematically represents an exploded view of a device according to the invention. This device is particularly suitable for the machining of a cylindrical monocrystalline bar 18 of standardized diameter for the production of the two locating flats. The device comprises a guide piece 30 having a first cylindrical housing 32 of revolution around a central axis CC. This housing 32 is intended to receive the bar 18 to be rectified, its diameter is therefore substantially equal but nevertheless greater than the standard diameter of the bar 18. For example, for a standard diameter of 2 inches (5.08 cm) the diameter of the housing 32 is 5.1 cm.

The guide piece 30 has a flat face 34 intersecting the diameter of the housing 32 so as to provide an opening 36. This opening 36 has a determined width which corresponds to the width of the large flat to be machined on the bar 18 (that is i.e. a width of 18 mm).

The bar 18 inserted inside the first housing 32 of the guide piece 30 must be oriented for the machining of the flats. To do this, thanks to a centering tip 12 hot-bonded to an end face of the bar 18, the bar 18 is secured to a hollow turntable 42, by means of a connecting piece 44 secured to the turntable 42 One end in relief 46 of the connecting piece 44 fits into a recess 38 in the end piece 12. The size of the end piece 12 is such that once introduced into the guide piece 30, the end piece 12 has no part extending beyond the opening 36 of the first housing 32.

The turntable 42 is supported by a hollow body 40. The turntable 42 and the hollow body 40 can be of the TR80 type manufactured by the company Micro-Contrôle, for example.

The connecting piece 44 is fixed to the turntable 42 by two screws 48; it crosses the turntable 42 and the hollow body 40 to be secured to the end piece 12 by two screws 54.

Advantageously, the centering end piece 12 is one of those already fixed to the bar 18 when the diameter is set, thus ensuring perfect concordance between the central axes of the bar 18 and the end piece 12 .

The bar 18 is introduced into the first housing 32 of the guide piece 30. The hollow body 40 is then fixed to one end of the guide piece 30 by means of two screws 50. These screws 50 are brought to the end of the guide piece 30 by a passage 52 machined over the entire height of the guide piece 30, for example.

Optionally, the centering of the assembly constituted by the turntable 42 and its body 40 can be improved by the use of a centering ring (not shown) interposed between the guide part 30 and the body 40.

The bar 18 is then suitably oriented inside the first housing 32 by X-ray diffraction on the part of the bar 18 projecting through the opening 36. The orientation is obtained by rotating the bar around the axis CC 18 inside the housing 32, by actuating a system 43 of adjusting screws coupled to a wheel setting in motion the turntable 42.

Once oriented, the bar 18 is held in position inside the housing 32 by means of fixing.

FIG. 4B schematically represents a transverse section along a plane perpendicular to the axis CC. This figure shows an embodiment of the means for fixing the bar 18 inside the housing 32.

This fixing means consists of a bar 60 arranged in a second housing 62 formed in the guide piece 30 and opening onto the first housing 32.

This bar 60 has a concave face 64 able to match the cylindrical contour of the bar 18.

When it is desired to fix the bar 18 inside the first housing 32, clamping screws 66 are actuated which exert pressure on said bar 60 by passing through threaded orifices made for this purpose in the guide piece 30.

In the embodiment shown in FIG. 4A and shown in section in FIG. 4B, it can be seen that the bar 60 is actuated by three clamping screws 66, which makes it possible to balance the pressure exerted on the bar 18.

Once the bar 18 is perfectly oriented in the first housing 32 of the guide piece 30, that is to say that the crystalline planes chosen ([110] for AsGa, for example) are parallel to the planar face 34 of the guide piece, then the small flat is machined.

To do this, the bar 18 is separated from the turntable 42 by unscrewing the screws 54 then the screws 50.

FIG. 5A schematically represents an exploded view of a device according to the invention used to make the small flat.

On each end of the guide piece 30 containing the bar 18 suitably oriented and fixed by the fixing means, a flange 70 is fixed having a flat face 72 of determined width, and projecting from the guide piece 30. Each flange 70 is by example fixed by screws 74. The planar face 72 of each flange 70 is positioned parallel to the face 34 of the guide piece 30 by means of a set of two pins 76 fitting into housings 78, 79 designed for this purpose in the flanges and in the guide piece 30.

FIG. 5B schematically represents an alternative embodiment of a flange allowing to machine a small flat.

In FIG. 5B, it can be seen that the flat face 72 of the flange 70 is positioned parallel to the face 34 of the guide piece 30 by means of a single pin 76 which fits into housings 78, 79 designed for this purpose. effect in the flange 70 and in the guide piece 30. The flange 70 also has a relief 75 capable of fitting into the first housing 32 of the guide piece 30.

Whatever the variant, the flat faces 72 of the flanges 70 are included in a plane cutting the diameter of the bar 18 projecting from the opening 36. The section generated has a width equal to the width of the small flat.

FIGS. 6A to 6D schematically represent the different stages of the production of the flats on a bar. The references used are the same as those used in the description of Figures 1 to 5. In this example, the small flat is machined first.

FIG. 6A schematically represents the orientation of the bar by the X-ray diffraction referenced RX. The bar 18 is inserted into the first housing of the guide piece 30 and secured to the turntable 42.

The bar 18 is subjected to the RX beam through the opening 36 made in the first housing 32 of the guide piece 30. By rotation of the bar 18, by acting on the turntable 42, the crystalline planes are oriented ([110] for AsGa for example) parallel to the flat face 34 of the guide piece 30.

The bar 18 is fixed in this orientation by acting on the screws 66. The turntable 42 is then separated from the bar 18 and removed, as well as the body 40 and the connecting piece 44, from the guide piece 30.

FIG. 6B schematically represents the device according to the invention allowing the realization of the small flat.

The flanges 70 are fixed to the guide piece 30, their planar face 72 parallel to the planar face 34.

Maintaining the bar 18 against a grinding wheel (not shown) allows the machining of the flat part 17. The machining is stopped when the grinding wheel comes into contact with the flat faces 72. The parallelism between the faces 72 of the flanges 70 and the flat face 34 of the guide piece 30 guarantees the orientation of the flat 17.

FIG. 6C schematically represents the device according to the invention allowing, after the realization of the small flat 17, to orient the bar 18 for the realization of the large flat.

The flanges 70 are disassembled is the bar 18 and again secured to the turntable 42. After having loosened the clamping screws 66, the bar 18 is subjected to a rotation of 90 °, then the clamping screws 66 are tightened.

The turntable 42 is then detached from the bar 18 and removed, as well as the body 40 and the connecting piece 44, from the guide piece 30.

Figure 6D shows the device according to the invention for making the large flat. Once the bar 18 is properly oriented and fixed inside the guide piece 30, its part extending beyond the opening is brought into contact with a grinding wheel (not shown).

The machining is stopped when the grinding wheel comes into contact with the flat face 34 of the guide piece 30. In this way, the orientation and the width of the large flat 19 are guaranteed.

FIG. 7 schematically represents the bar 18 once the two flats 17, 19 have been made. The device according to the invention makes it possible to guarantee an angular precision of at least ± 5 ′ and a precision over the widths of the flats 17, 19 of ± 0.5 mm.

The various manipulations in play are simple and reproducible. In addition, only one exposure to X-rays is used, which limits the risk of irradiation.

Claims (9)

1. Device for adjusting the crystal orientation and rectifying a bar (18), characterized in that it comprises:
- A guide piece (30) having a first housing (32) capable of receiving said bar (18), this first housing (32) having a longitudinal central axis (CC), said guide piece (30) having a flat face (34) cutting the first housing (32) so as to provide an opening (36) along the first housing (32), this opening (36) being of determined width,
- A fixing means capable of fixing the bar (18) inside the housing (32) of the guide piece (30). 2. Device according to claim 1, said bar being of cylindrical shape and having a standardized diameter, device characterized in that the first housing (32) is cylindrical of revolution around the central axis (CC), this first housing having a diameter substantially equal to but greater than the standard diameter. 3. Device according to claim 1, characterized in that the fixing means consists of:
- a bar (60) disposed in a second housing (62) formed in the guide piece (30) and opening onto the first housing (32),
- At least one clamping screw (66) exerting pressure on said bar (60), passing through a threaded orifice made for this purpose in the guide piece (30). 4. Device according to claim 3, characterized in that said strip (60) has a face (64) of concave shape. 5. Device according to claim 1, characterized in that it further comprises means for rotating said bar (18) around the central axis (CC) of the first housing (32) of the guide piece (30 ). 6. Device according to claim 5, characterized in that the means for rotating said bar (18) comprise:
a hollow rotary plate (42) about an axis of revolution, this plate (42) being supported by a body (40) capable of being fixed to one end of the guide piece (30),
- a connecting piece (44) integral with the turntable (42),
- a centering end piece (12) able to be fixed to an end face of the bar (18), an end in relief (46) of the connecting piece (44) being able to fit into a recess (38) of the end piece (12) so as to ensure centering of the bar (18) inside the first housing (32), this end piece (18) being secured to the connecting piece (44) by a fixing means so that a rotation of the turntable (42) causes a rotation of the bar (18), this end piece (12) having a size such that once introduced into the guide piece (30), the end piece (12) does not have no part extending beyond the opening (36) of the first housing (32). 7. Device according to claim 1, characterized in that it comprises:
two flanges (70) capable of being fixed by fixing means (74) at each end of the guide piece and each having a flat face (72) of determined width, and projecting from the guide piece (30),
- Positioning means capable of positioning the flat face (72) of each flange (70) parallel to the flat face (34) of the guide piece (30). 8. Device according to claim 7, characterized in that the positioning means consist of two pins (76) by flange (70) to be positioned, each pin (76) being able to fit into housings (78, 79) made for this purpose in each flange (70) and in the guide piece (30). 9. Device according to claim 7, characterized in that the positioning means consist of a pin (76) by flange (70) to be positioned, this pin being able to fit into housings (78, 79) made at this effect in each flange (70) and in the guide piece (30) and in a relief (75) capable of fitting into the first housing (32) of the guide piece (30).

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