JP3749305B2 - Wafer polishing equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wafer polishing apparatus.
A wafer polishing apparatus includes a polishing apparatus and a lapping apparatus. The basic structure of the polishing apparatus includes a wafer holding unit, a polishing surface plate having a polishing surface arranged opposite to the wafer holding unit and polishing the wafer, and a wafer surface for contacting the wafer surface with the polishing surface. A contact / separation mechanism for moving the holding part and the polishing surface plate toward and away from each other, a pressing mechanism for pressing the wafer held by the holding part of the wafer against the polishing surface with a predetermined pressing force, and the wafer abutting against the polishing surface of the polishing surface plate A drive mechanism for moving the wafer and the polishing platen relative to each other by rotating and / or reciprocating while being in contact with and pressed, a supply mechanism for a liquid abrasive containing slurry, and the like are provided. The polishing surface plate is a surface plate configured by fixing a cloth or a felt-like cloth, or a sponge or short brush-like member on the surface of a surface plate body made of a metal plate or a ceramic plate, and its surface plate. It is configured to include a surface plate receiving part that receives and supports the board.
According to this polishing apparatus, it is possible to polish a wafer that is a thin member to be polished (for example, a surface of a brittle member such as a silicon wafer for a semiconductor device or a glass thin plate member) into a mirror surface.
[0002]
[Prior art]
In a conventional wafer polishing apparatus, a surface plate is simply placed on a surface plate receiving portion that receives and supports the surface plate. As the surface plate main body, which is the base of the surface plate, a material having high rigidity is used because high flatness is always required to improve the polishing accuracy of the wafer. In particular, the flatness of the silicon wafer that is the raw material of the semiconductor chip is required to have submicron accuracy, so the surface plate body is not allowed to be slightly deformed, and the surface plate body is required to have extremely high rigidity. . In order to increase the rigidity, it is only necessary to increase the thickness of the surface plate body, so the surface plate body is very heavy. In addition, as for the material of the conventional surface plate main body, stainless steel is generally used in the case of a polishing apparatus because of its chemical resistance, and in the case of a lapping apparatus, cast iron is used.
[0003]
By the way, since the surface plate body is very heavy, there are the following advantages. That is, when the surface plate is placed on the surface plate receiving portion, it is not easily lifted or skids due to its weight even if it is simply placed without being fixed by screwing or the like. Also, if the material of the surface plate body and the surface plate receiving part are different, the coefficient of thermal expansion will be different, so if the surface plate body and the surface plate receiving part are completely fixed together, it will warp in a bimetallic shape due to temperature changes Can be considered. However, when the surface plate is simply placed on the surface plate receiving portion, the force due to thermal expansion can be released, so that the problem of warp as described above does not occur. In addition, since the surface plate is merely placed on the surface plate receiving portion, there is no need for a work process for fixing means (for example, screw fixing) when attaching and detaching the polishing surface plate, and it is accompanied by re-stretching of the cloth, etc. Easy to attach and detach the surface plate.
[0004]
[Problems to be solved by the invention]
However, since the surface plate is very heavy, the work of attaching and detaching the surface plate is never easy and dangerous. In particular, in the case of a polishing apparatus, it is necessary to change the cloth frequently (for example, once every few days), and the weight of the surface plate has become a problem with respect to its handling. Further, when the weight of the surface plate is increased, there is a problem that the motion mechanism for driving the surface plate is increased in size. Furthermore, when the surface plate body and the surface plate receiving portion are considered comprehensively, the rigidity may be excessively set.
[0005]
Therefore, an object of the present invention is to maintain the flatness of the surface plate body as usual, and to fix the surface plate to the surface plate receiving portion, and to reduce the weight of the surface plate. An object of the present invention is to provide a wafer polishing apparatus capable of easily attaching and detaching a surface plate at the time of replacement.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention comprises the following arrangement.
That is, the present invention polishes a wafer by bringing the wafer surface into contact with the polishing surface of the polishing surface plate and polishing the wafer surface by relatively moving the wafer and the polishing surface plate while applying a predetermined load to the wafer. In the apparatus, the polishing platen provided with a surface plate having a polishing surface, and a surface plate receiving portion for receiving and supporting the surface plate, and the surface plate and the surface plate receiving portion are integrated with the wafer. And a vacuum device for adsorbing the surface plate and the surface plate receiving portion to each other, and the surface plate receiving portion is composed of two flat plate portions and rotates the surface plate. And a groove-like circulation channel that allows cooling water to circulate is formed between the two flat plate portions, and the circulation channel is connected to a cooling water supply channel that penetrates the shaft portion. It is characterized by communicating with the cooling water discharge path .
[0007]
Further, a packing for watertightly sealing between the flat plate portions is provided between the two flat plate portions of the surface plate receiving portion.
Further, the surface plate has a main body made of a ceramic plate.
Further, a groove-like vacuum passage for vacuum-sucking the surface plate is formed on the surface of the surface plate receiving portion on which the surface plate is placed, and the vacuum passage is formed in the passage formed in the shaft portion. characterized in that it communicates.
In the surface plate receiving portion, the area of the vacuum passage is set wider than the area receiving the surface plate.
[0008]
A support base that rotatably supports the surface plate and the surface plate receiving portion integrally adsorbed to each other around an axis perpendicular to the polishing surface of the surface plate; A rotation driving means for rotating the surface plate about the axis with respect to the support base, a base supporting the support base, and the support base parallel to the polishing surface with respect to the base By providing a circular motion device that performs a circular motion that does not rotate in a smooth plane, the wafer can be more uniformly and suitably polished.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a schematic sectional view showing an embodiment of a wafer polishing apparatus according to the present invention, and FIG. 2 is a plan view schematically showing the configuration of the embodiment of FIG. In FIGS. 1 and 2, the wafer surface is brought into contact with the polishing surface 10a of the polishing surface plate 10, and the wafer 20 and the polishing surface plate 10 are relatively moved while applying a predetermined load to the wafer 20. A mechanism on the polishing surface plate 10 side in a wafer polishing apparatus for mirror polishing the surface is shown. FIG. 3 is a cross-sectional view showing details of the configuration of the polishing surface plate 10.
[0010]
The polishing surface plate 10 is provided so as to be divided into a surface plate receiving portion 12 and a surface plate 14 placed on the surface plate receiving portion 12, and the surface plate 14 is adsorbed on the surface plate receiving portion 12. It is detachably fixed by. That is, the surface plate 14 and the surface plate receiving portion 12 are provided so as to be attracted to each other by a vacuum device (not shown) so that they can move relative to the wafer 20 as a unit. .
[0011]
The surface plate 14 includes a metal plate or a ceramic plate as a base (hereinafter referred to as a surface plate body), and a cloth or a felt-like cloth, or a sponge or short brush-like member is fixed on the surface thereof. .
If the surface plate 14 is a ceramic plate, the weight can be reduced and the rigidity can be improved. For example, if the surface plate 14 is a ceramic mainly composed of alumina, the density is about 3.9 g / cc, which is about half the density of the cast iron material (about 7.9 g / cc). Therefore, the weight can be reduced to about half, and the attaching / detaching work of the surface plate 14 at the time of changing the cloth can be easily performed.
In addition, since the weight is reduced when the surface plate 14 is a ceramic plate in this way, the effect of integration with the surface plate receiving portion 12 due to the weight is reduced. However, since the surface plate 14 is fixed to the surface plate receiving portion 12 by vacuum suction, the surface plate 14 and the surface plate receiving portion 12 can be reliably integrated.
By the way, weight reduction of the surface plate 14 is also possible by making the plate | board thickness thin. The rigidity of the polishing surface plate 10 depends on both the surface plate 14 and the surface plate receiving portion 12, and the surface plate 14 may not have to have a predetermined rigidity or more.
[0012]
Moreover, the surface plate receiving part 12 is comprised by the flat plate part 12a, 12b of two layers. A shaft portion 16 is integrally fixed to the flat plate portion 12b, and a surface plate receiving portion 12 is formed in which the shaft portion 16 is integrally protruded in a direction opposite to the surface receiving the surface plate. The material of the surface plate receiving portion 12 is preferably a material that is hardly deformed by heat. For example, a low thermal expansion material (for example, a special cast iron material) can be used. As the low thermal expansion material, the linear expansion coefficient is 3.0 × 10 ⁻⁶ / K · 20-100 ° C. or less, and as a high precision material, the linear expansion coefficient is 1.0 × 10 ⁻⁶ / K · 20. The thing below -100 degreeC is known.
By adopting the surface plate receiving portion 12 from such a material that is hardly deformed by heat, the polishing accuracy of the wafer can be improved. That is, if the deformation of the surface plate receiving portion 12 is small, the surface plate 14 is fixed following the shape of the surface plate receiving portion 12, and therefore, it is possible to prevent the flatness thereof from being lowered.
In addition, when the surface plate 14 is ceramics mainly composed of alumina as described above, the linear expansion coefficient is about 7.0 × 10 ⁻⁶ / K · 40-500 ° C. According to this, since the surface plate 14 is fixed to the surface plate receiving portion 12 so that the force due to thermal expansion can be released, it does not warp in a bimetallic shape and the flatness does not decrease.
[0013]
A groove-like vacuum passage 15 for vacuum-sucking the surface plate 14 is formed on the surface of the platen portion 12a of the surface plate receiving portion 12 on which the surface plate 14 is placed. The vacuum passage 15 is formed on the surface of the flat plate portion 12a as shown in FIG. 4, and communicates with a vacuum source (not shown) through the passage 15a of the shaft portion 16.
As shown in FIG. 4, the vacuum passage 15 has a larger area than the area that receives the surface plate 14 in order to increase the suction force, and is formed almost uniformly over the entire surface. Thus, it is possible to prevent the surface plate 14 from being deformed due to the dispersion of the adsorption force.
A gasket 17 is formed in a ring shape with a V-shaped cross section. Further, as shown in FIG. 3, when the surface plate 14 is attracted to the surface plate receiving portion 12, a secret seal is made.
[0014]
A circulating water channel 13 through which cooling water can circulate is formed between the flat plate portion 12b and the flat plate portion 12a. The circulating water path 13 communicates with a cooling water supply path 13a and a cooling water discharge path 13b penetrating the shaft portion 16, and cooling water is supplied and circulated by a cooling water supply source and a cooling water suction device (not shown). Reference numeral 17a denotes a ring-shaped packing which provides a watertight seal between the flat plate portion 12a and the flat plate portion 12b.
The circulating water channel 13 provided on the surface of the flat plate portion 12b is in the form of a groove as shown in FIG. Thus, the cooling water introduction port 13c and the discharge port 13d are provided so as to be on opposite sides of the groove, and are formed in a pleat shape because the cooling water is circulated with directionality and the cooling water is suitable for the entire surface. This is because the cooling efficiency is improved by circulation.
In addition, as a power unit which introduces cooling water, for example, a trochoid pump which is a suction device can be used. In the case of suction, no matter how much the degree of vacuum is increased, the pressure is only 1 atm, and there is an advantage that the deformation of the polishing platen does not exceed a certain level. Of course, a high-pressure flow may be used.
[0015]
Reference numeral 12 c denotes a pin fixed to the flat plate portion 12 a and is fitted into a concave portion 14 a provided on the surface plate 14. A plurality of pins 12c and recesses 14a are provided (two in this embodiment), and are used for positioning the surface plate 14 with respect to the surface plate receiving portion 12. The pin 12c also has a role of preventing the side plate 14 from slipping.
The recess 14a formed on the surface plate 14 is formed of stainless steel (SUS). The reason why the pins 12c are engaged with the surface plate 14 made of ceramics through the SUS material is to protect the surface plate 14 by dispersing the force applied to the brittle ceramics by the pins 12c.
[0016]
Reference numeral 22 denotes a support base, which supports the polishing surface plate 10 so as to be rotatable about an axis perpendicular to the polishing surface 10a. The shaft portion 16 of the polishing surface plate 10 is inserted into a through-hole 22a that passes through the center of the support base portion 22, and the polishing surface plate 10 is supported by the thrust bearing 23 and the radial bearings 18, 18, 19, and 19. The part 22 is rotatably supported around its axis.
[0017]
Reference numeral 25 denotes a rotation driving means which is mounted on the support base 22 and rotates the polishing surface plate 10 around the axis with respect to the support base 22. The rotation driving means 25 includes, for example, a rotation motor 24 (see FIG. 2) fixed to the support base 22 and a worm gear 26 fixed to the output shaft of the rotation drive motor 24 as in the present embodiment. And a worm wheel 27 meshed with the worm gear 26 and fixed to the polishing surface plate 10 side. The worm wheel 27 is connected and fixed so as to rotate integrally by the shaft portion 16 and the key 28.
Reference numeral 29 denotes a distributor unit, which can supply and discharge cooling water to and from the circulation water channel 13 even when the shaft unit 16 rotates by a mechanism substantially similar to the distributor unit 92 of the wafer pressing device 40 described later. A vacuum source is provided so as to communicate with the vacuum passage 15.
[0018]
Reference numeral 30 denotes a base that supports the support base 22. The base 30 shown in FIG. 1 is a part of the frame of the apparatus main body, and is actually fixed on the base surface by a support frame (not shown).
Reference numeral 32 denotes a circular motion device which causes the base 30 to perform a circular motion that does not rotate the support base 22 in a plane parallel to the polishing surface 10a. The circular motion device 32 includes, for example, an eccentric arm 34 and a circular motion motor 36 as in the present embodiment.
[0019]
The eccentric arm 34 has a base-side shaft 35 rotatably provided on the base 30 around an axis parallel to the axis of the polishing surface plate 10, and is parallel to the base-side shaft 35 and has a predetermined axis. A shaft 38 on the side of the support base that is rotatably provided on the support base 22 around an axis that is eccentric in the distance is integrally formed in a crank shape. As shown in FIG. 2, the eccentric arm 34 having the same shape and having the same eccentric distance L between the base side shaft 35 and the support base portion side shaft 38 is disposed between the base 30 and the support base portion 22. It is arranged in three places. In the present embodiment, the case where the eccentric arms 34 are arranged at three positions has been described. However, the present embodiment is not limited to this, and in order to support the support base 22 on the base 30 in a well-balanced manner, the number of the eccentric arms 34 is increased to four or more. Of course, it may be arranged.
[0020]
The circular motion motor 36 operates as a circular motion driving means that causes the eccentric arms 34 disposed at at least three locations to rotate synchronously and cause the support base portion 22 to perform a circular motion that does not rotate with respect to the base 30. The circular motion motors 36 are arranged corresponding to the eccentric arms 34 and are fixed to the base 30. Note that even one circular motion motor 36 can drive the support base 22. Of course, the circular motion drive means may not be directly connected to the eccentric arm 34 as in the case of a circular motion motor, and may be any mechanism that can suitably rotate the shaft 35 on the base side.
[0021]
Next, the wafer pressing device 40 will be described with reference to FIG.
The wafer pressing device 40 is positioned above the polishing surface plate 10, holds the wafer 20 so that the wafer surface comes into contact with the polishing surface 10 a of the polishing surface plate 10, and holds the wafer 20 on the polishing surface of the polishing surface plate 10. Press 10a.
Reference numeral 50 denotes a holding member, which can hold the wafer 20 on the surface 50a by the surface tension of a liquid such as water (water in this embodiment). The holding member 50 is formed by using a ceramic plate as a base material, and a backing material which is an elastic material and adsorbs the wafer 20 is adhered to the surface of the ceramic plate by adhesion or the like. The material of the backing material is a microporous sheet made of a polymer material mainly composed of polyurethane, and is easily adapted to and closely adheres to the wafer 20 due to its elasticity.
[0022]
A template 52 is attached to the surface of the holding member 50 by adhesion. The template 52 is formed in a ring shape and surrounds the periphery of the wafer 20 to prevent the wafer 20 from sliding. The inner diameter of the template 52 is set so that the side slip of the wafer 20 is suppressed and the wafer 20 is easily fitted inside. Further, the thickness is set to about two-thirds of the thickness of the wafer 20. The template 52 may be mounted in a fitting manner.
[0023]
53 is a recessed part and is open | released toward the downward direction. Reference numeral 54 denotes a plate-like elastic member, which is formed in a donut-shaped flat plate shape by, for example, a hard rubber plate material, the outer peripheral portion is fixed to the outer peripheral step portion of the inner upper surface of the recess 53, and the inner peripheral portion is the holding member 50. It is fixed to the upper surface and suspends the holding member 50 in an up and down direction and a horizontal direction in an allowable range within a minute range.
Reference numeral 55 denotes a pressure chamber, and the recess 53 is defined by a holding member 50 and a plate-like elastic member 54. A fluid having a predetermined pressure can be supplied into the pressure chamber 55 by a fluid supply means (not shown).
[0024]
Reference numeral 62 denotes a main shaft, which is formed in a cylindrical shape, and a pipe 64 communicating with a compressed air source (not shown) as a high-pressure fluid source is inserted into the cylinder. The tube 64 communicates with the pressure chamber 55, and compressed air is introduced into the pressure chamber 55 when the surface of the wafer 20 is brought into contact with the polishing surface 10 a (see FIG. 1) of the polishing surface plate 10. Then, a uniform pressure is applied to substantially the entire upper surface of the holding member 50. Thereby, the surface of the wafer 20 can be pressed against the polishing surface 10a by applying a uniform load to the entire surface by a desired pressure. At this time, since the compressed air filled in the pressure chamber 55 is a fluid (air in this embodiment), the entire surface of the holding member 50 is evenly pressed, and the surface of the wafer 20 is caused to quickly follow the inclination of the polishing surface 10a. be able to.
[0025]
Reference numeral 66 denotes a base member which is movably provided to supply the wafer 20 held by the holding member 50 onto the polishing surface 10a and to discharge the wafer 20 from the polishing surface 10a. Further, a wafer holding portion 42 fixed to the tip of the main shaft 62 is rotatably supported via the main shaft 62 and the like.
[0026]
Reference numeral 68 denotes a locking portion, which is provided at the upper part of the main shaft 62 and has a smaller diameter than the lower side. The locking portion 68 is locked to an arm portion 74 fixed to the rod 72 of the cylinder device 70 via bearing portions 76 and 76 that are supported in both the rotational and thrust directions. Further, the main shaft 62 provided integrally with the wafer holding portion 42 is inserted into a rotation transmission member 80 provided rotatably with respect to the base member 66 via rotation bearings 78, 78. The rotary bearings 78 and 78 are mounted in a standing cylinder portion 82 that is integrally fixed to the base member 66. The rotation transmission member 80 and the main shaft 62 are connected by a key 84 fixed on the main shaft 62 side facing a key groove 81 provided on the rotation transmission member 80 side. For this reason, the rotation transmission member 80 and the main shaft 62 rotate integrally. In addition, since the key groove 81 is long in the axial direction that is the longitudinal direction, the main shaft 62 can be moved in the vertical direction with respect to the base member 66 within a predetermined range by the cylinder device 70. In FIG. 3, the wafer holder 42 is moved upward by the cylinder device 70.
Reference numeral 86 denotes a drive motor, which rotates the rotation transmission member 80 to which the driven gear 90 is connected by the key 91 via the pinion gear 88 and the driven gear 90. The rotation transmitting member 80 is provided so as to be rotatable with respect to the base member 66 by rotating bearings 78 and 78 disposed between the rotation transmitting member 80 and the base member 66.
[0027]
Reference numeral 92 denotes a distributor unit, which is a connection port unit for communicating with a compressed air source. The front end 62a of the main shaft 62 fitted in the distributor 92 is received so that the front end 62a can rotate. Reference numeral 94 denotes a communication path that communicates with the pipe 64. Reference numeral 96 denotes a seal member. A ring-shaped space 97 is formed around the seal member 96, 96, and a high-pressure source connection port 98 is provided in communication with the ring-shaped space 97. It has been. For this reason, even if the tip 62a rotates, the compressed air source can always communicate with the pressure chamber 55 through the high pressure source connection port 98, the ring-shaped space 97, the communication path 94, and the pipe 64.
Reference numeral 100 denotes an encoder device that functions as a detection device for a fixed position stop device that detects the rotational position of the main shaft 62 and stops the wafer holder 42 at a predetermined position.
[0028]
According to the wafer polishing apparatus having the above-described movement mechanism, the polishing surface plate 10 does not rotate the support base portion 22 by the plurality of eccentric arms 34, but circular movement (this circular movement not rotating will be described below). The movement is simply a circular movement) and the movement that rotates (rotates) with respect to the support base 22 is a combined movement. On the wafer pressing device 40 side, the wafer holding portion 42 moves so as to rotate (spin) the wafer 20.
Unlike the rotational motion, the circular motion is a motion in which any point on the polishing surface plate 10 generates the same speed, and any point on the wafer 20 can be polished under the same conditions. Therefore, the surface of the wafer 20 can be polished very uniformly and accurately. When the other conditions are the same, the flatness of 0.5 μm for an 8-inch silicon wafer in the conventional wafer polishing apparatus can be easily reduced to 0.2 μm or less with the wafer polishing apparatus of the present invention. It came to be obtained. Further, since the polishing can be performed uniformly in this way, the wear of the cloth and the like constituting the polishing surface of the polishing surface plate 10 can be made uniform, the adjustment work of the polishing surface plate 10 can be simplified, and the polishing operation can be made efficient.
[0029]
The wafer polishing apparatus described above uses a holding member 50 to which a backing material is bonded as a ceramic plate of a wafer pressing apparatus. This is because ceramics has a smaller coefficient of linear expansion than metal materials and is difficult to deform, and is therefore effective for polishing the wafer 20 uniformly and accurately, but instead of ceramic plates, metal materials or resin materials are used. Of course, a plate made of may be used.
In addition, the holding member is not limited to a plate-like form that is difficult to be deformed, but also includes a thin film formed by an elastic member. Even with such a holding member, the wafer 20 can be brought into contact with the polishing surface 10a with a uniform pressure through liquid pressure.
[0030]
Further, the wafer holding unit 42 holds the wafer 20 by sticking the wafer 20 to the holding member 50 by water sticking, but is not limited to this, and may have another configuration. For example, the wafer holding unit 42 that presses the wafer 20 in a state where the wafer 20 is not attracted when the wafer 20 is attracted and held, supplied and discharged, and actually polished may be used.
In the embodiment described above, the case where the wafer 20 is pressed against the polishing surface by the compressed air via the holding member 50 has been described. However, other fluid pressures such as water pressure or hydraulic pressure may be used.
When the holding member 50 is provided in a large size so as to hold a plurality of wafers 20, a plurality of holes into which the wafers 20 are fitted are provided in the template 52, and the plurality of wafers 20 are polished simultaneously. can do.
[0031]
In the above embodiment, the case where the polishing platen is applied to the above-described wafer polishing apparatus that rotates around the central axis and circularly moves to prevent uneven polishing of the wafer has been described. The invention is not limited to this, and in terms of reducing the weight of the surface plate and facilitating the replacement operation, the movement mechanism that polishes the wafer uniformly by rotating the surface plate and reciprocating (oscillating) linearly. Of course, the present invention can also be suitably applied to a wafer polishing apparatus including
The preferred embodiments of the present invention have been described above in various ways. However, the present invention is not limited to these embodiments, and it goes without saying that many more modifications can be made without departing from the spirit of the invention. That is.
[0032]
According to the wafer polishing apparatus of the present invention, the surface plate and the surface plate receiving portion can be removed by a vacuum device so that the surface plate and the surface plate receiving portion can move integrally with each other. Can be adsorbed to each other.
Therefore, according to the present invention, the flatness of the surface plate body can be suitably maintained as before, the surface plate can be securely fixed to the surface plate receiving portion, and the weight of the surface plate can be reduced to reduce the cross. There is a remarkable effect that the work of attaching and detaching the surface plate can be easily performed at the time of replacement .
[Brief description of the drawings]
FIG. 1 is a sectional view showing an embodiment of a wafer polishing apparatus according to the present invention.
FIG. 2 is a schematic plan view of the embodiment of FIG.
FIG. 3 is a cross-sectional view showing details of a polishing surface plate of the embodiment of FIG. 1;
4 is a plan view showing one form of a vacuum passage of the embodiment of FIG. 1. FIG.
FIG. 5 is a plan view showing one embodiment of a circulating water channel in the embodiment of FIG. 1;
FIG. 6 is a cross-sectional view of a wafer pressing device used in the wafer polishing apparatus according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Polishing surface plate 10a Polishing surface 12 Surface plate receiving part 12a Flat plate part 12b Flat plate part 12c Pin 13 Circulating water channel 14 Surface plate 14a Recess 15 Vacuum passage 16 Shaft part 20 Wafer 22 Supporting base part 24 Rotation drive motor 25 Rotation drive means 26 Worm gear 27 Worm wheel 30 Base 32 Circular motion device 34 Eccentric arm 35 Base side shaft 36 Circular motion motor 38 Support base side shaft 40 Wafer pressing device

Claims (6)

In a wafer polishing apparatus for bringing a wafer surface into contact with a polishing surface of a polishing surface plate and relatively moving the wafer and the polishing surface plate while applying a predetermined load to the wafer to polish the wafer surface,
A polishing platen provided with a platen having a polishing surface, and a platen receiving part for receiving and supporting the platen ;
A vacuum device for mutually adsorbing the surface plate and the surface plate receiving portion so that the surface plate and the surface plate receiving portion can move together relative to the wafer ;
The surface plate receiving portion is composed of two layers of flat plate portions, and is fixed integrally to a shaft portion for rotating the surface plate, and a groove-like circulation through which cooling water can circulate between the two layers of flat plate portions. A wafer polishing apparatus , wherein a water channel is formed, and the circulating water channel communicates with a cooling water supply channel and a cooling water discharge channel penetrating the shaft portion . 2. The wafer polishing apparatus according to claim 1, wherein a packing for sealing the space between the flat plate portions is provided between the two flat plate portions of the surface plate receiving portion. 3. The wafer polishing apparatus according to claim 1, wherein the surface plate has a main body made of a ceramic plate. A groove-like vacuum passage for vacuum-sucking the surface plate is formed on the surface of the surface plate receiving portion on which the surface plate is placed, and the vacuum passage communicates with a passage formed in the shaft portion. wherein the are wafer polishing apparatus as described in any one of claims 1 to 3. 5. The wafer polishing apparatus according to claim 4, wherein in the surface plate receiving portion, an area of the vacuum passage is set wider than an area receiving the surface plate. A support base that rotatably supports the surface plate and the surface plate receiving portion integrally attached to each other so as to be rotatable around an axis perpendicular to the polishing surface of the surface plate;
Rotation driving means mounted on the support base and rotating the surface plate about the axis with respect to the support base;
A base for supporting the support base,
Any one of claims 1 to 5, characterized by comprising a circular motion device against the base board to the circular motion without rotating the support section in the polishing surface and the plane parallel to The wafer polishing apparatus as described.

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