JP2004298970A - Vacuum chuck - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vacuum chuck whereby adhesion between its adsorbing surface and a work is improved by almost eliminating level differences made on the adsorbing surface of the vacuum chuck. <P>SOLUTION: This vacuum chuck 1 is furnished with a porous body 10 having a surface 10a on which suction force works and a porous supporting body 5 on which a storage groove 7 to tightly store the porous body 10 in it is formed. The porous body 10 and the porous supporting body 5 are constituted of the same fluoride resin and both of them are connected to each other by welding on such the vacuum chuck 1. Consequently, the porous body 10 and the porous supporting body differently become porous or compact. Consequently, hardness and Young's modula of them extremely become approximate to each other, and it is possible to extremely reduce the level differences even when surfaces 5a, 10a of both of them are surface-ground and to improve the adhesion of the work and the adsorbing surface 1a. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a vacuum chuck.
[0002]
[Prior art]
2. Description of the Related Art Generally, in a process of manufacturing a liquid crystal display panel or a semiconductor device, a vacuum chuck that holds a work on a suction surface thereof by suction when processing and transporting a work such as a liquid crystal glass or a semiconductor wafer is used. As a vacuum chuck, a vacuum chuck using a porous body in order to apply a uniform suction force to a work is conventionally known. By applying a suction force to the suction surface of the porous body through the internal fine holes, the work is suctioned to the suction surface, and the work is held in that state.
[0003]
As such a vacuum chuck, there is a vacuum chuck having a suction plate made of porous ceramics having a suction surface, and an outer peripheral seal layer made of dense ceramics having a housing groove for housing the suction plate. The outer peripheral seal layer houses the suction plate such that the surface thereof is flush with the suction surface of the suction plate, and the outer peripheral portion of the suction plate is sealed by the outer peripheral seal layer. Then, low-melting glass is used for joining the suction plate and the outer peripheral seal layer, and a low-melting glass layer is interposed between the two (see Patent Document 1).
[0004]
[Patent Document 1]
Registered Utility Model No. 255938
[0005]
[Problems to be solved by the invention]
By the way, when a vacuum chuck sucks a precision processing substrate such as a liquid crystal glass or a semiconductor wafer as a work on the suction surface of a suction plate, the suction surface is finished with high precision in order to increase the flatness of the surface. In the finishing process, the surface on the suction side of the vacuum chuck, that is, the suction surface of the suction plate and the surface of the outer peripheral seal layer (suction plate support) are both ground.
[0006]
When such a surface grinding is performed on the above-described conventional vacuum chuck, there is a problem that a step is generated between the suction surface of the suction plate and the surface of the outer peripheral seal layer even if the flatness is to be increased. . This is because a low-melting glass layer made of a material different from that of the suction plate and the outer peripheral seal layer is interposed as an adhesive. In this regard, in the above-described conventional vacuum chuck, a technique has been devised to impregnate the outer peripheral portion of the suction plate with low-melting glass so as to approximate the mechanical properties of the outer peripheral seal layer and reduce the level difference. However, since a low-melting glass made of a material different from that of the suction plate and the outer peripheral sealing layer is still used as the adhesive, a step of several μm is generated.
[0007]
When such a step occurs, the degree of adhesion between the work and the vacuum chuck decreases. In a process such as an etching process in which a chemical solution is used while adsorbing a work, the lower the degree of adhesion, the greater the amount of the chemical solution entering between the work and the suction surface of the vacuum chuck. As a result, the degree of erosion of the contact surface of the workpiece and the suction-side surface of the vacuum chuck by the penetrated chemical liquid also increases.
[0008]
Usually, the surface of the porous adsorbent plate is formed to be lower than the surface of the dense outer peripheral seal layer due to Young's modulus, hardness and other characteristics. Such a step creates a state in which the workpiece is in contact with the surface of the outer peripheral sealing layer but is not in contact with the surface of the inner suction plate. If a suction force is applied to the suction plate in such a state, there is also a problem that the work in the non-contact state is sucked, thereby bending the work and possibly damaging the work.
[0009]
Therefore, an object of the present invention is to provide a vacuum chuck that can solve the above problem.
[0010]
Means for Solving the Problems and Effects of the Invention
Hereinafter, means and the like that can solve the above-mentioned problems will be enumerated in separate sections. The operation, effects, specific means, and the like will be additionally described as necessary.
[0011]
Means 1. A porous body having a suction surface; and a closing portion having a work contact surface that closes the periphery of the porous body and is flush with the suction surface. In a vacuum chuck for adsorbing a work on an adsorption surface by acting on the adsorption surface through a hole,
A vacuum chuck, wherein the porous body and the closing portion are made of the same thermoplastic resin, and both are joined by welding.
[0012]
According to Means 1, since the porous body and the closed portion are made of the same thermoplastic resin, the only difference between them is that they are porous or dense. The two members are joined by welding, for example, heat welding, and there is no material of a different material such as an adhesive between them. Thermoplastic resins do not have high hardness like ceramics and metals, and the difference in Young's modulus between porous and dense is almost negligible. Therefore, even if both the suction surface of the porous body and the work contact surface of the closed portion are ground to improve the flatness, there is almost no step between the two surfaces. For this reason, when a work is adsorbed on the adsorption surface of the porous body and the work contact surface of the closing portion, the degree of adhesion between the both surfaces and the work becomes extremely high. Thus, even when a process using a chemical solution such as an etching process is performed, the intrusion of the chemical solution can be sufficiently suppressed, and the erosion of the adsorption surface and the work contact surface by the penetrated chemical solution can be prevented. In addition, since the step generated between the two surfaces is extremely small, it is possible to prevent the sucked work from being damaged by the step.
[0013]
Means 2. A support having a housing groove for densely housing the porous body is provided, and the porous body is fixedly supported in a state where the porous body is housed in the housing groove. The vacuum chuck according to claim 1, wherein:
[0014]
According to the means 2, since the closing portion is constituted by the peripheral wall of the accommodation groove, the outer peripheral portion of the porous body is closed by the peripheral wall. The closing portion may be formed by heating and deforming the outer peripheral portion of the porous body to close the micropores in the outer peripheral portion. In this case, suction is performed at the closed portion on the adsorption surface of the porous body. The force cannot be applied. In this regard, according to the means 2, the suction force can be applied to the entire suction surface of the porous body. Therefore, the entire adsorption surface of the porous body can be effectively used.
[0015]
Means 3. A porous body having a suction surface, and a support for supporting the porous body at a position retracted from the suction surface, wherein suction force from a vacuum source is applied to the suction surface through micropores inside the porous body. In the vacuum chuck which sucks the work on the suction surface by acting on
The porous body is made of a thermoplastic resin, and an outer peripheral portion of the porous body is heated and pressurized and deformed to close micropores of the porous body, thereby forming a seal layer on the outer peripheral portion. And vacuum chuck.
[0016]
According to the means 3, since the outer peripheral seal layer of the porous body is formed by closing the porous micropores by heat and pressure deformation, the porous body to be the adsorption surface and the seal layer are made of the same heat. Since they are made of a plastic resin, the only difference between them is that they are porous or dense. Since the seal layer is formed by closing the micropores on the outer peripheral portion of the porous body by heat and pressure deformation as described above, a different material such as an adhesive is used between the porous body and the seal layer. Does not exist. Thermoplastic resins do not have high hardness like ceramics and metals, and the difference in Young's modulus between porous and dense is almost negligible. Therefore, even if both the suction surface of the porous body and the work contact surface of the seal layer are ground to improve the flatness, there is almost no step between both surfaces. For this reason, when a work is adsorbed on the adsorption surface of the porous body and the work contact surface of the seal layer, the degree of adhesion between the both surfaces and the work becomes extremely high. Thus, even when a process using a chemical solution such as an etching process is performed, the intrusion of the chemical solution can be sufficiently suppressed, and the erosion of the adsorption surface and the work contact surface by the penetrated chemical solution can be prevented. In addition, since the step generated between the two surfaces is extremely small, it is possible to prevent the sucked work from being damaged by the step. In the case where the outer peripheral sealing layer of the porous body is formed by heating and pressing deformation, the outer peripheral portion of the porous body is melted by heating and pressing and deforming the outer peripheral portion of the porous body near its melting point. Together with the action, the seal layer can be easily formed. In particular, since the outer peripheral seal layer is formed not only by melting by heating but also by applying pressure to the outer peripheral portion, the outer peripheral seal layer can be formed reliably and quickly.
[0017]
Means 4. A porous body having a suction surface, and a closing portion that closes the periphery of the porous body and has a work contact surface that is flush with the suction surface, and has an inner surface on the suction surface side of the porous body. A vacuum, in which a concave portion sealed by a sealing layer is provided, and a suction force from a vacuum source is applied to a suction surface around the concave portion through micropores inside the porous body to suction a workpiece onto the suction surface. A chuck,
A vacuum chuck, wherein the porous body and the closing portion are made of the same thermoplastic resin, and both are joined by welding.
[0018]
In the means 4, since the concave portion is formed on the suction surface of the porous body, even if an electric circuit portion such as a wiring pattern is also formed on the contact surface side of the work, the electric circuit is accommodated in the concave portion. By doing so, the work can be sucked without damaging the circuit section. Since the porous body and the closing portion are made of the same thermoplastic resin, the only difference between them is whether they are porous or dense. The two members are joined by welding, for example, heat welding, and there is no material of a different material such as an adhesive between them. Therefore, according to the means 4, the same operation and effect as those of the means 1 can be obtained.
[0019]
Means 5. A support having a housing groove for densely housing the porous body is provided, and the porous body is fixedly supported in a state where the porous body is housed in the housing groove. A vacuum chuck according to claim 4, wherein:
[0020]
According to the means 5, since the closing portion is constituted by the peripheral wall of the accommodation groove, the outer peripheral portion of the porous body is closed by the peripheral wall. The closing portion may be formed by heating and deforming the outer peripheral portion of the porous body to close the micropores in the outer peripheral portion. In this case, suction is performed at the closed portion on the adsorption surface of the porous body. The force cannot be applied. In this regard, according to the means 5, the suction force can be applied to the entire surface of the adsorption surface of the porous body excluding the concave portion. Therefore, in a porous body having a concave portion and a limited adsorption area, the adsorption area can be used as widely as possible.
[0021]
Means 6. The vacuum chuck according to claim 4 or 5, wherein the sealing layer is made of a fluororesin.
[0022]
In the means 6, since the sealing layer is made of the fluororesin, even if the chemical solution enters the recess, the sealing layer can be prevented from being eroded, and the circuit portion of the substrate to be adsorbed is prevented from being contaminated. it can. In addition, since it has excellent heat resistance, even if a gas at the same temperature as the chemical is supplied into the recess, there is almost no effect on the sealing layer, and a gas at an appropriate temperature matching the temperature of the chemical is introduced into the recess. Can supply. For this reason, it is possible to prevent the temperature of the work in the recess from lowering, and to prevent the processing unevenness of the work.
[0023]
Means 7. The vacuum chuck according to any one of means 1 to 6, wherein the thermoplastic resin is a fluororesin.
[0024]
In the means 7, the same fluororesin is used as the thermoplastic resin constituting the porous body (and the closed portions in the means 1 and 4, and the support in the means 2 and 5). Fluororesin has excellent chemical resistance and heat resistance to chemicals such as an etchant among thermoplastic resins, so that the durability of the vacuum chuck can be improved. In particular, in the combination of the means 6 and the means 7, since the porous body, the closing portion, and the sealing layer are all made of a fluororesin, the effects shown in the means 6 become more remarkable.
[0025]
Means 8. A porous body having a suction surface, and a support having a work contact surface that is densely accommodated in the porous body and is flush with the suction surface. In a vacuum chuck for adsorbing a work on an adsorption surface by acting on the adsorption surface through a hole,
A vacuum chuck, wherein the porous body and the support are made of a thermoplastic resin, and both are joined by welding.
[0026]
According to the means 8, since the porous body and the support are made of a thermoplastic resin, it is possible to join them by welding, for example, heat welding. In the means 8, since both the porous body and the support are joined by welding, no adhesive or the like exists between them. When joining is performed by using an adhesive, the joining force is obtained by partial joining by an anchor effect, and therefore, there is a problem that a difference is caused in the joining force depending on the size of micropores opened in the joining surface of the porous body. On the other hand, since the joining by welding is a surface joining, the size of the fine pores of the porous body is irrelevant, and a stronger joining force can be obtained as compared with the joining force using an adhesive. Therefore, according to the means 8, the bonding strength between the porous body and the support can be enhanced.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
Hereinafter, a first embodiment will be described with reference to FIGS. 1 to 3. 1 is a plan view of the vacuum chuck according to the first embodiment, FIG. 2 is a cross-sectional view taken along line AA of FIG. 1, and FIG. FIG. 4 is a cross-sectional view showing a step of joining
[0028]
As shown in FIGS. 1 and 2, the vacuum chuck 1 includes a chuck body 2 formed in a bottomed cylindrical shape. The chuck body 2 is made of a metal material such as stainless steel. The cross-sectional shape of the chuck body 2 is not particularly limited. A suction port 4 communicating with the inner space 3 of the chuck body 2 is formed at the bottom center of the chuck body 2. The suction port 4 may be formed in various forms, such as forming a female screw hole in which a female screw for connecting a pipe is formed, or providing a one-touch joint. When the vacuum chuck 1 is used, a pipe from a suction device (not shown) is connected to the suction port 4.
[0029]
On the opening side of the chuck main body 2, a porous support 5 (support) formed to have the same outer shape as the chuck main body 2 in plan view is provided, and the opening of the chuck main body 2 is opened by the porous support 5. The part is closed. The porous support 5 is densely formed of a synthetic resin material. The porous support 5 is fixed by bolts 6 as fastening members in a state where the outer peripheral surface of the lower surface thereof and the outer peripheral surface of the upper surface of the chuck main body 2 are joined. Note that the two may be fixed with an adhesive or other fixing means. By providing the porous support 5, the inner space 3 of the chuck body 2 is a closed space. A packing (not shown) is interposed on the joint surface between the chuck body 2 and the porous support 5 to prevent the inflow of fluid such as air existing around the joint surface from the joint surface when a suction force acts on the inner space 3. Have been. It is to be noted that, without using packing, it is also possible to form a surface seal for performing sealing by finishing the joining surface between the chuck main body 2 and the porous support 5 with high precision in a flat surface.
[0030]
On the surface 5 a (work contact surface) of the porous support 5, that is, on the surface opposite to the joint surface with the chuck body 2, a receiving groove 7 having a circular shape in plan view is formed. A plurality (three in the present embodiment) of annular grooves 8 having different diameters are formed concentrically on the bottom surface of the accommodation groove 7. The bottom surface of each annular groove 8 communicates with the suction port 4 via an intake passage 9 formed in the porous support 5 and an inner space 3 of the chuck body 2. One intake passage 9 is formed in each annular groove 8. For this reason, the space in the housing groove 7 is communicated with the suction port 4 via the annular groove 8, the intake passage 9, and the inner space 3. Note that a plurality of intake passages 9 may be formed for each annular groove 8.
[0031]
The disc-shaped porous body 10 is densely housed in the housing groove 7 so as to form the same plane as the surface 5a of the porous support 5 and is fixed in that state. The surface 5a of the porous support 5 and the surface 10a (adsorption surface) of the porous body 10 form a flush surface. The porous body 10 is formed by sintering a synthetic resin. In this configuration, the periphery of the porous body 5 is closed by the porous support 5, and the porous support 5 plays a role of a closing portion. In addition, the shape of the accommodation groove 7 and the porous body 10 can be selected as desired, such as a square shape. However, it is preferable that both have the same shape.
[0032]
When a suction force is applied to the suction port 4 by driving a suction device (not shown), the suction force is applied to the surface of the porous body 10 through the inner space 3, the intake passage 9, the annular groove 8, and the micropores inside the porous body 10. 10a. Thereby, air existing near the surface 10a of the porous body 10 is sucked.
[0033]
In the vacuum chuck 1 configured as described above, in a state where the workpiece is in contact with the surface 10a of the porous body 10 and the surface 5a of the porous support 5, the suction port 4 is driven by a suction device (vacuum source) (not shown). Apply suction force to Then, the suction force acts on the surface 10 a of the porous body 10 through the inner space 3, the intake passage 9, the annular groove 8, and the fine holes inside the porous body 10. Thereby, the work which is in contact with the surfaces 5a, 10a of the porous support 5 and the porous body 10 is adsorbed on the surfaces 5a, 10a. The surfaces 10a and 5a of the porous support 5 and the porous body 10 are the suction surface 1a (contact surface) of the vacuum chuck 1 for sucking the work. Then, as long as a suction force is applied to the suction port 4, the work is held in a state of being sucked on the suction surface 1a.
[0034]
Here, the porous support 5 and the porous body 10 are each made of the same synthetic resin. The synthetic resin specifically used is a trifluoride resin. The porous support 5 is formed by flowing a molten trifluoride resin into a mold and molding or shaving it from a molding material. The porous body 10 is filled with powdered trifluoride resin in a mold and sintered. In addition, as the synthetic resin to be used, it is also possible to use other fluororesin such as tetrafluoride resin, and it is also possible to use a thermoplastic resin other than fluororesin such as nylon resin and polyacetal resin. . Then, both the porous support 5 and the porous body 10 are joined by heat welding. Thermal welding is performed as follows.
[0035]
As shown in FIG. 3, a mold 16 is used for heat welding. On the upper surface 16 a of the mold 16, a housing portion 17 having substantially the same shape as the outer shape of the porous support 5 and housing the support 5 is formed. On the bottom surface of the housing 17, a flow groove 18 communicating with the opening of the intake passage 9 when the porous support 5 is housed in the housing 17 is formed. The mold 16 has an open passage 19 communicating the flow groove 18 with the outside of the mold 16. Therefore, when the porous support 5 is accommodated in the accommodation portion 17, the space in the annular groove 8 of the porous support 5 is outside the mold 16 via the intake passage 9, the flow groove 18, and the open passage 19. Are in communication.
[0036]
At the time of heat welding, the porous support body 5 in which the porous body 10 is housed in the housing groove 7 is housed in the housing part 17 of the mold 16, and then the weight 20 is placed on the entire mold 16. In the accommodated state, the surface 5a (here, the upper surface 5a) of the porous support 5 and the surface 10a (here, the upper surface 10a) of the porous body 10 are not flush with each other due to an error in the production and the like. Rather, the upper surface 10a of the porous body 10 is slightly projected. Similarly, the upper surface 5a of the porous support 5 and the upper surface 16a of the mold 16 are not flush with each other, but rather the upper surface 5a of the porous support 5 is slightly protruding. Therefore, a gap δ is formed between the bottom surface 20b of the weight 20 and the upper surface 16a of the mold 16. The weight of the weight 20 acts on the porous support 5 and the porous body 10 due to the gap δ.
[0037]
In this state, the whole is heated by a heating means such as an electric furnace. At this time, the heating is performed gradually over several hours to the melting point of the thermoplastic resin constituting the porous support 5 and the porous body 10. For example, in the case where ethylene trifluoride chloride resin (PCTFE) is used, its melting point is 212 ° C., so that it is heated to that temperature.
[0038]
Then, the surface layers of the porous support 5 and the porous body 10 are in a melted state. At this time, since the weight of the weight 20 is acting on the porous support 5 and the porous body 10, the pressure generated by the weight 20 also causes the contact between the porous support 5 and the porous body 10. Welded together. In addition, at the time of this heat welding, since the flow groove 18 and the open passage 19 are formed in the mold 16, the temperature unevenness of the contact surface between the porous support 5 and the porous body 10 is reduced. Thermal welding of the contact surface is performed uniformly. In addition, since the mold 16 is present on the outer peripheral side of the porous support 5, the mold 16 is pressed down and deformation due to thermal expansion of the porous support 5 is suppressed, and thereby the outer peripheral portion of the porous body 10 The formation of a gap between the support and the porous support 5 is also suppressed.
[0039]
Since the heating is performed gradually as described above, the welding of the porous support 5 and the porous body 10 proceeds gradually. The progress of the welding is indicated by the width of the gap δ generated between the weight 20 and the mold 16. When the gap δ disappears, it is determined that the welding has been completed, and the heating is stopped there, and thereafter, it is naturally cooled.
[0040]
After the porous support 5 and the porous body 10 are thermally welded in this manner, both the surface 10a of the porous body 10 and the surface 5a of the porous support 5 are ground as a finishing treatment. By this surface grinding, both surfaces 5a and 10a are made flat surfaces and the flatness of the flat surfaces is enhanced. At this time, the porous support 5 and the porous body 10 are made of the same thermoplastic resin, and the only difference between them is that they are porous or dense. And since both are joined by heat welding, there is no thing of a different material between them.
[0041]
Here, the thermoplastic material does not have high hardness like ceramics and metal, and the difference in Young's modulus between porous and dense is almost negligible. For this reason, when both the surface 10a of the porous body 10 and the surface 5a of the porous support 5 are ground, the level of the step between both surfaces is only on the order of submicron, and is about several μm in the prior art. Is also negligible compared to some steps.
[0042]
For this reason, when a work is sucked on the suction surface 1a of the vacuum chuck 1 (the surface 10a of the porous body 10 and the surface 5a of the porous support 5), the degree of adhesion between the suction surface 1a and the work is extremely high. Get higher. Accordingly, even when a process using a chemical solution such as an etching process is performed, the penetration of the chemical solution can be sufficiently suppressed, and the erosion of the adsorption surface 1a and the contact surface of the workpiece by the penetrated chemical solution can be prevented. In addition, since the step generated between the two surfaces is extremely small, it is possible to prevent the work from being damaged by the step.
[0043]
When an adhesive is used for joining the porous support 5 and the porous body 10, the joining force is obtained by partial joining by the anchor effect. However, there is a problem that the joining force using the anchor effect is different depending on the size of the fine holes opened in the joining surface of the porous body 10. In this regard, since the joining by thermal welding is a surface joining as in the present embodiment, the size of the fine holes is irrelevant, and a stronger joining force can be obtained as compared with the joining force using an adhesive.
[0044]
Further, in the present embodiment, since a fluororesin called a trifluoride resin is used, the synthetic resin is excellent in chemical resistance and heat resistance to a chemical such as an etchant among synthetic resins. In addition, since the porous support 5 and the porous body 10 are formed of a fluororesin, which is a trifluoride resin, and both are thermally welded, it is not necessary to use an adhesive such as an epoxy resin. An adhesive such as an epoxy resin has many problems in chemical resistance and heat resistance, and it is not necessary to use such a material. Therefore, the durability of the vacuum chuck 1 using the porous body 10 made of a synthetic resin is not required. Can be improved.
[0045]
In addition, configuring the vacuum chuck 1 using a porous body has the following advantages. That is, since the work is adsorbed on the entire surface 10a of the porous body 10, a uniform suction force acts on the work, and the work can be prevented from being deformed due to the suction. Further, since the surface temperature of the work at the time of suction can be made uniform, it is possible to prevent processing unevenness due to a temperature change.
[0046]
In the above-described embodiment, the porous support 5 and the porous body 10 are joined by heat welding. However, they may be joined by welding them using high frequency, ultrasonic waves, frictional heat, or the like. It is possible.
[0047]
Further, as shown in FIG. 4, it is also possible to form a vacuum chuck 23 in which the porous support 24 and the porous body 25 have the same outer shape in plan view. In this configuration, the porous support 24 does not necessarily need to be made of a synthetic resin. When it is made of other materials such as metal, it is joined to the porous body 25 by an adhesive or the like. Further, since the outer peripheral portion of the porous body 25 is not closed by the porous support 24, it is necessary to provide a seal layer 26 (closed portion) on the outer peripheral portion. This seal layer 26 is formed as follows.
[0048]
As shown in FIG. 5A, the seal forming die 27 includes a drop groove 28 and a heater 29 as a heating unit for heating the seal forming die 27. The peripheral surface 28a in the drop groove 28 is formed in a tapered shape such that the cross section increases continuously from the bottom surface of the groove 28. On the bottom surface of the drop groove 28, an open passage 30 is formed which communicates with the inside of the drop groove 28 and the outside of the seal forming die 27. Although the heater 29 is provided on the bottom surface of the seal forming die 27, other configurations such as being built in the die 27 may be adopted.
[0049]
On the other hand, with respect to the porous body 25, first, the mold 31 is filled with powdered trifluoride resin and sintered to form the prototype 31. The molded model 31 is formed in a flat plate shape having substantially the same shape as the shape of the drop groove 28 in a plan view. However, the outer peripheral surface 31a is formed in a taper shape having an acute angle than the taper formed on the peripheral surface 28a of the drop groove 28. Further, of the two parallel planes constituting the plate-shaped prototype 31, the surface with the smaller area is the lower surface 31b, and the lower surface 31b is formed so as to correspond to the shape of the opening of the drop groove 28. I have.
[0050]
The mold 31 having such a shape is placed on the seal forming mold 27 so that the lower surface 31b and the opening of the drop groove 28 are aligned. At this time, since the lower surface 31 b of the prototype 31 is formed so as to correspond to the opening of the drop groove 28, the prototype 31 does not fall into the drop groove 28. In this state, the seal forming die 27 is heated by the heater 29. The heating temperature is a temperature near the melting point of the trifluoride resin forming the prototype 31. In the case where ethylene trifluoride chloride resin (PCTFE) is used as in the present embodiment, the melting point is 212 ° C., so that the resin is heated to 200 to 210 ° C.
[0051]
As shown in FIG. 5B, the prototype 31 made of a trifluoride resin, which is a thermoplastic resin, is softened by the heat of the same mold 27 at a portion in contact with the seal forming mold 27. Then, since the outer peripheral surface 31a of the prototype 31 and the peripheral surface 28a of the drop groove 28 are formed in a tapered shape, the prototype 31 starts to gradually descend into the drop groove 28 by its own weight. At this time, the outer peripheral portion of the prototype 31 is thermally melted according to the shape of the peripheral surface 28a of the drop groove 28. In the process of the prototype 31 falling under its own weight, the outer periphery of the prototype 31 is pressed toward the inner periphery based on its own weight. Then, the thermal melting of the outer peripheral portion is combined with the own weight drop (pressurization) of the prototype 31, and the fine holes existing in the outer peripheral portion of the prototype 31 are crushed. Therefore, as the prototype 31 falls under its own weight, the seal layer 26 is formed on the outer periphery thereof. As shown in FIG. 5C, when the entire prototype 31 is finally housed in the drop groove 28, the seal layer 26 is formed on the entire outer peripheral portion of the prototype 31. When the seal layer 26 is formed, not only the outer peripheral portion of the prototype 31 is heated but also pressurized as described above, so that the fine holes are surely crushed as compared with the case where the outer peripheral portion is simply heated. And the time required for its formation is also reduced.
[0052]
Thereafter, the master 31 on which the seal layer 26 is formed is taken out from the seal forming mold 27 and naturally cooled. After the cooling, the prototype 31 is processed into a predetermined shape to form the porous body 25.
[0053]
Since the seal layer 26 formed on the outer peripheral portion of the porous body 25 merely closes the micropores originally possessed by heating and pressurizing deformation, the porous body 25 also has the same thermoplastic resin as a whole. (Trifluoride resin). There is no material of a different material between the porous portion and the seal layer 26. Therefore, even with this configuration, when the surface 25a of the porous body 25 is ground, even if a step is generated between the surface of the porous portion and the surface of the seal layer 26, the step can be made extremely small. The degree of adhesion between the suction surface of chuck 23 (the surface 25a of porous body 25) and the workpiece can be increased.
[0054]
[Second embodiment]
Hereinafter, a second embodiment will be described with reference to FIGS. 6 and 7. FIG. 6 is a plan view of the vacuum chuck according to the second embodiment, and FIG. 7 is a sectional view taken along line BB of FIG.
[0055]
As shown in FIGS. 6 and 7, the vacuum chuck 41 includes a base 42 that is densely formed of a synthetic resin. The base 42 is formed in a circular shape in plan view, but may be formed in any other shape such as a square shape. A port 43 is formed on the outer surface of the base 42. The port 43 may be formed in various forms, such as forming a female screw hole in which a female screw for connecting a pipe is formed, or providing a one-touch joint. When the vacuum chuck 41 is used, a pipe from a suction device (not shown) is connected to the port 43. This is the same for the ports described below.
[0056]
In the base 42, a receiving groove 44 having a circular shape in a plan view is formed on a plane (hereinafter, referred to as a surface 42a) where the port 43 is not formed. A passage 45 is formed in the base 42 and opens at the bottom of the accommodation groove 44, and the interior of the accommodation groove 44 communicates with the port 43 via the passage 45. An annular groove 46 is formed on the bottom surface of the housing groove 44 on the outer edge side. The annular groove 46 is formed in a circular shape that forms a concentric circle with the housing groove 44 in a plan view, but may be formed in any other shape such as a square shape. Further, on the bottom surface of the accommodation groove 44, one or a plurality of connection grooves 47 connecting the annular groove 46 and the opening of the passage 45 are formed. In the present embodiment, since there are five connecting grooves 47, each connecting groove 47 is formed to extend radially from the opening of the passage 45 in plan view as shown in FIG.
[0057]
A disk-shaped porous body 48 is densely accommodated in the accommodation groove 44 so as to form the same plane with the surface 42a of the base 42, and is fixed in that state. The surface 42a of the base 42 and the surface 48a of the porous body 48 form a flush flat surface. The porous body 48 is formed by sintering a synthetic resin. The shape of the accommodation groove 44 and the porous body 48 can be arbitrarily selected, such as a square shape in plan view. However, it is preferable that both have the same shape.
[0058]
A concave groove 49 is formed on the surface 48 a of the porous body 48. The concave groove 49 is formed in a circular shape that is concentric with the porous body 48 in a plan view, but may be formed in any other shape such as a square shape. In the concave groove 49, a disk-shaped mask plate 50 (sealing layer) densely formed of a synthetic resin and formed thinner than the depth of the concave groove 49 is densely accommodated. By accommodating the mask plate 50, a concave portion 51 is formed on the surface 48 a of the porous body 48. Note that the depth of the concave portion 51 is actually about 0.1 to 0.2 mm. Further, a configuration in which a resin layer coated with a synthetic resin is provided on the inner surface where the concave groove 49 is formed instead of the mask plate 50 as the sealing layer may be employed.
[0059]
When a suction force acts on the port 43 by driving a suction device (not shown), the suction force is applied to the surface of the porous body 48 through the passage 45, the connection groove 47, the annular groove 46, and the fine holes in the porous body 48. 48a. Thereby, air existing near the surface 48a of the porous body 48 is sucked. Note that, due to the presence of the mask plate 50, no suction force acts on the portion of the porous body 48 joined to the mask plate 50.
[0060]
Further, a plurality of supply ports 52 are formed on the outer surface of the base 42 where the accommodation grooves 44 are not formed. A plurality of gas passages 53 are formed in the base 42 for each supply port 52, and each supply port 52 is communicated with the inside of the recess 51 through each gas passage 53. When the vacuum chuck 41 is used, a pipe from a gas supply device (not shown) for supplying a chemically stable gas such as nitrogen gas is connected to each supply port 52. When the gas is supplied from the gas supply device to the supply port 52, the gas is supplied into the recess 51 through the gas passage 53. In addition, switching means such as a switching valve is provided in the pipe from the gas supply device, and gas can be exhausted by switching to the atmosphere open state by the switching means.
[0061]
In the vacuum chuck 41 configured as described above, the substrate W as a work is brought into contact with the surface 48a of the porous body 48 and the surface 42a of the base 42 as shown in FIG. At this time, the electric circuit P formed on the surface that comes into contact with the surfaces 42 a and 48 a of the base 42 and the porous body 48 is accommodated in the recess 51. Therefore, the electric circuit P is not broken by the contact with the vacuum chuck 41.
[0062]
In this state, a suction force is applied to the port 43 by driving a suction device (vacuum source) not shown. Then, the suction force acts on the surface 48 a of the porous body 48 via the passage 45, the connecting groove 47, the annular groove 46, and the fine holes inside the porous body 48. As a result, the substrate W in contact with the surfaces 42a, 48a of the base 42 and the porous body 48 is adsorbed on the surfaces 42a, 48a. The surfaces 42a, 48a of the base 42 and the porous body 48 are the suction surfaces 41a of the vacuum chuck 41 for sucking the substrate W. Then, as long as the suction force is applied to the port 43, the substrate W is held in a state of being sucked on the suction surface 41a.
[0063]
When an etching process is performed on the substrate W, the substrate W is immersed in an etching liquid in this suction holding state. At this time, a gas having the same temperature as the etching liquid is supplied to the gas supply / discharge port 52 from a gas supply device (not shown). Then, the gas is supplied into the concave portion 51 through the port 52 and the gas passage 53, and the concave portion 51 is filled with a gas having the same temperature as the etching liquid. This can prevent a decrease in the surface temperature of the substrate W due to the presence of the space of the concave portion 51.
[0064]
Here, the base 42, the porous body 48, and the mask plate 50 are each made of the same synthetic resin. The synthetic resin to be used specifically is a trifluoride resin as in the first embodiment. It is also possible to use another fluororesin such as a tetrafluoride resin or to use a thermoplastic resin other than a fluororesin such as a nylon resin or a polyacetal resin. Then, both the base 42 and the porous body 48 are joined by heat welding, and the surfaces 42a, 48a are both ground as a finishing process so as to be flush with each other, and the flatness of the flat surface is enhanced. This is also the same as in the first embodiment.
[0065]
Therefore, the only difference between the base 42 and the porous body 48 is that the base 42 is porous or dense, and there is no material of a different material between them. For this reason, also in the second embodiment, when both the surfaces 42a and 48a of the base 42 and the porous body 48 are ground, it is possible to extremely reduce the level difference generated between both surfaces. Thereby, the degree of adhesion between the suction surface 41a of the vacuum chuck 41 (the surfaces 42a and 48a of the base 42 and the porous body 48) and the substrate W is increased, so that the infiltration of the etching solution during the etching process can be prevented, and the step difference can be prevented. Damage to the substrate can also be prevented.
[0066]
In addition, the bonding between the base 42 and the porous body 48 can have a stronger bonding force than the bonding force using an adhesive, and is excellent in chemical resistance and heat resistance by using a fluororesin. This is the same as in the first embodiment described above, in that durability is improved by not using an adhesive such as an epoxy resin.
[0067]
Further, in the second embodiment, the mask plate 50 serving as a sealing layer is also made of a fluororesin. For this reason, it is effective when performing a process using a chemical solution such as an etching process on the work sucked and held by the vacuum chuck 41. That is, since a sealing layer made of an epoxy resin is conventionally provided on the inner surface of the concave groove 49 of the porous body 48, the epoxy resin is eroded by the chemical solution that has entered the concave portion 51, and the epoxy resin becomes particles. There is a problem that the electric circuit P in the concave portion 51 is contaminated. In this regard, the excellent chemical resistance of the fluororesin can prevent the mask plate 50 from being eroded even if a chemical solution enters the recess 51, thereby preventing the electric circuit P from being contaminated. In addition, since it is excellent in heat resistance, even if a gas having the same temperature as the chemical is supplied into the recess 51, there is almost no effect on the sealing layer, and a gas having an appropriate temperature in accordance with the temperature of the chemical is supplied to the recess 51. Can be supplied within. For this reason, it is possible to prevent the temperature of the substrate W from decreasing in the concave portion 51 and prevent the occurrence of processing unevenness of the substrate W.
[Brief description of the drawings]
FIG. 1 is a plan view of a vacuum chuck according to a first embodiment.
FIG. 2 is a sectional view taken along line AA of FIG.
FIG. 3 is a sectional view showing a step of joining a porous support and a porous body using a mold.
FIG. 4 is a sectional view showing another example of the first embodiment.
FIG. 5 is a cross-sectional view showing a process of manufacturing a porous body in another example.
FIG. 6 is a plan view of a vacuum chuck according to a second embodiment.
FIG. 7 is a sectional view taken along line BB of FIG. 6;
[Explanation of symbols]
1, 41: vacuum chuck, 5: porous support (support), 5a: surface (work contact surface) 7: accommodation groove, 10, 25: porous body, 10a, 25a: surface (adsorption surface), 26 ... Seal layer (closed portion), 50 ... Mask plate (sealing layer), 51 ... Recess, W ... Substrate (work).

Claims (8)

A porous body having a suction surface; and a closing portion having a work contact surface that closes the periphery of the porous body and is flush with the suction surface. In a vacuum chuck for adsorbing a work on an adsorption surface by acting on the adsorption surface through a hole,
A vacuum chuck, wherein the porous body and the closing portion are made of the same thermoplastic resin, and both are joined by welding. A support having a housing groove for densely housing the porous body is provided, and the porous body is fixedly supported in a state where the porous body is housed in the housing groove. The vacuum chuck according to claim 1, wherein: A porous body having a suction surface, and a support for supporting the porous body at a position retracted from the suction surface, wherein suction force from a vacuum source is applied to the suction surface through micropores inside the porous body. In the vacuum chuck which sucks the work on the suction surface by acting on
The porous body is made of a thermoplastic resin, and an outer peripheral portion of the porous body is heated and pressurized and deformed to close micropores of the porous body, thereby forming a seal layer on the outer peripheral portion. And vacuum chuck. A porous body having a suction surface, and a closing portion that closes the periphery of the porous body and has a work contact surface that is flush with the suction surface, and has an inner surface on the suction surface side of the porous body. A vacuum, in which a concave portion sealed by a sealing layer is provided, and a suction force from a vacuum source is applied to a suction surface around the concave portion through micropores inside the porous body to suction a workpiece onto the suction surface. A chuck,
A vacuum chuck, wherein the porous body and the closing portion are made of the same thermoplastic resin, and both are joined by welding. A support having a housing groove for densely housing the porous body is provided, and the porous body is fixedly supported in a state where the porous body is housed in the housing groove. 5. The vacuum chuck according to claim 4, wherein: The vacuum chuck according to claim 4, wherein the sealing layer is made of a fluorine resin. 7. The vacuum chuck according to claim 1, wherein the thermoplastic resin is a fluororesin. A porous body having a suction surface, and a support having a work contact surface that is densely accommodated in the porous body and is flush with the suction surface. In a vacuum chuck for adsorbing a work on an adsorption surface by acting on the adsorption surface through a hole,
A vacuum chuck, wherein the porous body and the support are made of a thermoplastic resin, and both are joined by welding.

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