DE102019210497A1 - RAILING DEVICE AND RAIL SYSTEM - Google Patents

Abstract

A rail device (206, 208) for moving components (102, 104) of a lithography system (100A, 100B), comprising a guide rail (212, 284), and a roller package (210) with rotatably mounted rollers (240, 242, 244, 246), wherein the guide rail (212, 284) a tread element (214) on which roll in the operation of the rail device (206, 208), the rollers (240, 242, 244, 246), and a support member (216), the Tread element (214) carries, and wherein the tread element (214) and the support member (216) are positively connected to each other.

Description

The present invention relates to a rail device for moving components of a lithography system and a rail system with such a rail device.

Microlithography is used to fabricate microstructured devices such as integrated circuits. The microlithography process is performed with a lithography system having an illumination system and a projection system. The image of a mask (reticle) illuminated by means of the illumination system is projected onto a photosensitive layer (photoresist) coated in the image plane of the projection system substrate, for example a silicon wafer, by the projection system to the mask structure on the photosensitive coating of the substrate transferred to.

Driven by the quest for ever smaller structures in the manufacture of integrated circuits, EUV lithography systems (EUVs) are currently being developed which emit light having a wavelength in the range of 0.1 nm to 30 nm, in particular 13.5 nm , use. In such EUV lithography equipment, because of the high absorption of most materials of light of that wavelength, reflective optics, that is, mirrors, must be substituted for refractive optics, that is, lenses, as heretofore.

In the production of a lithography system as explained above, it may be necessary to subject individual modules or components of the lithography system, such as the beam-forming and illumination system or the projection system, to a cleaning. For this purpose, cleaning systems with residual gas analysis can be used. The beam shaping and illumination system or the projection system may have a mass of about 8 t or about 15 t. In order to load or unload such a cleaning system, a rail system can be used, on which the component of the lithography system to be cleaned can be placed.

In the production of the aforementioned modules and components, it is also necessary to check their optical performance. For this purpose, appropriate measuring systems are used. Also in these measuring systems, the components must be introduced. Preferably, this is also realized by means of rail systems.

Since such cleaning systems or measuring systems work in ultrahigh vacuum (UHV), the usable materials are very limited. In order to be able to move the mass of the component to be cleaned and to minimize particle generation, the rolling resistance of the rail system must be low and plastic deformation of the rail surface by the Hertzian pressure must be prevented. The surface pressure can be minimized by an adapted geometry selection. The remaining Hertzian pressure must then be absorbed by the components of the rail system, which requires a high hardness.

In addition, it must be prevented that when changing from one rail system, such as a loading car, on another rail system, such as a cleaning system, shocks, shocks or other force peaks occur that can lead to a misalignment of the component.

The occurring loads, namely the voltage peaks in the material, occur at a depth of a few tenths of a millimeter. Due to this, a minimum hardening depth of more than 1 mm is necessary. A surface hardening of stainless steel with little distortion is not feasible with the asymmetrical geometry of known rails. A process in which steel receives a higher surface hardness due to the diffusion of other substances and no distortion occurs, such as nitriding, is insufficient due to the small layer thickness.

Against this background, an object of the present invention is to provide an improved rail system.

Accordingly, a rail device for moving components of a lithography system is proposed. The rail device comprises a guide rail, and a roller assembly with rotatably mounted rollers, wherein the guide rail comprises a tread element on which roll in the operation of the rail device, and a support member which carries the tread element, and wherein the tread element and the support member with each other form fit are connected.

Characterized in that the functions supporting structure and running surface of the guide rail on two separate components, namely the tread element and the support member, are separated, it is possible to use for the tread element, for example, a hardened and thus abrasion resistant material. At the same time, a material which is tougher than the tread element can be used for the support element. Here, for example, an uncured material can be used, so that a design of a geometry of the support element is not limited by an expected delay in curing.

The components may include, for example, a beam forming and illumination system, a projection system or any other components of the lithography system. The components can also be referred to as components or modules. In particular, the lithography system can be modular. The roller package is particularly suitable to perform a linear movement with the help of the rollers along the guide rail. The rollers can also be referred to as rollers. In particular, the rollers are rotatably mounted in or on the roller package. For this purpose, a suitable storage, for example, a roller bearing can be provided.

In particular, the tread element and the support element are two separate components which are positively connected with each other. A positive connection is created by the meshing or grasping of at least two connection partners. For example, the tread element is bolted to the support member, riveted, jammed or otherwise firmly connected together. Preferably, the tread element is separable from the support element. The separability can be ensured for example by means of a screw connection. Preferably, the support element is a double-T-beam.

According to one embodiment, the support element is made of an unhardened steel alloy, in particular of unhardened stainless steel, wherein the running surface element is made of a hardened steel alloy, in particular of hardened stainless steel.

The support element and the tread element may be made of the same steel alloy or different steel alloys. The tread element is in particular surface-hardened or surface-hardened. The minimum hardening depth is preferably more than 0.5 mm.

According to a further embodiment, the tread element has two V-shaped treads or a flat tread.

"V-shaped" means that the two treads are inclined to each other. In the event that the tread is flat or flat, in particular exactly one tread is provided. Preferably, two guide rails are provided, wherein the one guide rail, the tread element with the V-shaped arranged treads and the other guide rail has the tread element with the flat running surface. The two V-shaped arranged running surfaces are preferably not plan, but have a curvature with a radius of, for example, greater than 200 mm. As a result, the Hertzian pressure can be kept small. In addition, these radii in combination with a spherical roller on the flat tread ensure that even with a deflection of the component to be supported between the rails, for example sagging due to its own weight, the support points on the guide rails can adjust and thus no constraining forces skip the component. Alternatively, the running surfaces of the tread element can also be performed V-shaped and without radii. In this case, the rollers are then additionally provided with a crown with a radius of greater than 200 mm. Similarly, the plane running surface of the tread element can be performed crowned and cylindrical rollers are used.

According to a further embodiment, the tread element facing away from the V-shaped running surfaces on two V-shaped arranged chamfers.

With the help of the V-shaped arranged running surfaces and the V-shaped chamfers, an approximately rotationally symmetrical structure of the tread element can be achieved. In this way, a distortion of the tread element during curing of the same can be prevented or at least reduced.

According to a further embodiment, the support element has two V-shaped bearing surfaces on which the chamfers rest.

As mentioned above, the support element is preferably a double-T-carrier with two edge sections, which are connected to each other by means of a web portion. At one of the edge portions of the bearing surfaces are provided. Spacers or spacers may be provided between the bearing surfaces and the tread element, so that the tread element can be adjusted in its position.

According to a further embodiment, the tread element has an octagonal or a rectangular cross-sectional geometry.

As a result, an approximately symmetrical, in particular rotationally symmetrical, construction of the tread element can be achieved. This reduces the distortion when curing the tread element. In the event that the tread element has an octagonal cross-sectional geometry, this includes the aforementioned V-shaped treads and the V-shaped chamfers arranged. In the event that the tread element has a quadrangular cross-sectional geometry, this includes the aforementioned flat tread.

According to a further embodiment, the rollers are individually spring-mounted in the roller package.

This means in particular that each roller is assigned at least one spring element. As a result, for example, gaps between two adjacent tread elements can be easily overcome. With the help of the resilient mounting shocks, shocks or other force peaks can be prevented or at least reduced, which can lead to a misalignment of the component.

According to a further embodiment, each roller is associated with a receiving element in or on which the respective roller is rotatably mounted, each receiving element is mounted individually resiliently in a housing of the roll package.

Preferably, each roller is associated with an axle which is mounted in the corresponding receiving element. The rollers are rotatably mounted on their associated axes. For this purpose, a rolling bearing is preferably provided. In order to transfer the high Hertzian pressure, all-ceramic bearings are preferred. Due to their high hardness, dry running without much abrasion is possible. Alternatively, steel rolling bearings can be used with a special UHV-compatible and dry-running coating.

According to a further embodiment, each receiving element is associated with at least one spring element which is arranged between the respective receiving element and the housing.

The housing is preferably closed by means of at least one clamping lid. With the help of the clamping cover, the spring elements can be biased. The spring elements are preferably so-called Schraubentellerfedern. Alternatively, stacked disc springs can be used. In this case, a measure is required, for example, a central guide pin, which prevents the stacked disc spring packet from slipping or tilting.

According to a further embodiment, each receiving element is associated with at least one guide pin which guides the respective receiving element linearly in or on the housing.

The guide pins are preferably so-called sword pins. Preferably, each receiving element associated with two guide pins. The guide pins prevent tilting of the receiving elements in the housing. The guide pins are preferably passed through the spring elements. The sword pins also allow a small angle compensation of the stored role to the guide rail. This is necessary when the component bends strongly, the roller packages have a small angular error to the longitudinal direction, or two tread elements are not perfectly aligned with each other.

According to a further embodiment, the rollers each have two V-shaped treads or a spherical tread.

However, the running surfaces of the rollers can also be cylindrical. "Ballig" means that the tread is curved.

According to a further embodiment, the rail device further comprises a plurality of tread elements, which are arranged one behind the other in a longitudinal direction of the rail device, wherein the support element carries the plurality of tread elements.

That is, a support member carries a plurality of tread elements. Each tread element preferably has a length of about 0.5 to 1.5 m. As a result, the delay during curing can be minimized. The guide rail itself may have a length of about 5 m. "In a row" means that the tread elements viewed in the longitudinal direction are arranged so that the tread elements follow one another.

According to a further embodiment, the rail device further comprises a spacer, in particular a spacer, which is arranged on an edge portion of the support element facing away from the tread element.

The spacer is a spacer or can be referred to as a spacer. The spacer is preferably plate-shaped. The aforementioned edge portion of the support element can be fastened by means of supports to a support structure, for example on a hall floor. Below the edge portion of the spacer or spacer may be provided. For aligning the guide rail such spacers can be used on each support. These can be ground in as needed. Thus, a tilt and / or a height offset can be compensated.

Furthermore, a rail system with at least one such rail device is proposed.

The rail system preferably comprises two rail devices. However, the rail system may also have only one rail device or more than two rail devices. The rail system is preferably part of a previously explained cleaning equipment, an optical measuring system, a loading car for these systems, a trolley with which the components can be moved in the clean room, a mounting stand on which said components can be mounted or completed, or a storage rack on which said components can be stored. In particular, all above-mentioned applications in common that a rail height above a floor and a track width of the guide rails for all applications of a component is identical, so that the component without the aid of a crane can be pushed from one rail system to another rail system.

According to one embodiment, the rail system further comprises a first rail device and a second rail device, wherein the first rail device functions as a fixed bearing of the rail system, and wherein the second rail device functions as a movable bearing of the rail system.

By the fact that the first rail device acts as a "fixed bearing" is to be understood in particular that the first rail device does not allow movement perpendicular to the longitudinal direction. The first rail device thus allows a side guide. This can be achieved in that the rollers and the tread element each have V-shaped arranged running surfaces. By the fact that the second rail device acts as a "floating bearing" is to be understood in particular that the second rail device, in contrast to the first rail device allows a movement perpendicular to the longitudinal direction. The second rail device thus allows no side guidance. This can be achieved in that the rollers have a crowned or cylindrical running surface and the tread element has a plane or even running surface.

In the present case, "a" is not necessarily to be understood as restricting to exactly one element. Rather, several elements, such as two, three or more, may be provided. Also, any other count word used herein is not to be understood as being limited to just the stated number of elements. Rather, numerical deviations up and down are possible, unless stated otherwise.

The embodiments and features described for the rail device apply to the proposed rail system and vice versa.

Further possible implementations of the invention also include not explicitly mentioned combinations of features or embodiments described above or below with regard to the exemplary embodiments. The skilled person will also add individual aspects as improvements or additions to the respective basic form of the invention.

• 1A zeigt eine schematische Ansicht einer Ausführungsform einer EUV-Lithographieanlage;
• 1B zeigt eine schematische Ansicht einer Ausführungsform einer DUV-Lithographieanlage;
• 2 zeigt eine schematische Aufsicht einer Ausführungsform einer Reinigungsanlage zum Reinigen von Komponenten einer Lithographieanlage gemäß 1A oder 1B;
• 3 zeigt eine schematische Schnittansicht einer Ausführungsform einer Schienenvorrichtung für die Reinigungsanlage gemäß 2;
• 4 zeigt die Detailansicht IV gemäß 3;
• 5 zeigt eine schematische perspektivische Ansicht einer Ausführungsform eines Rollenpakets für die Schienenvorrichtung gemäß 3;
• 6 zeigt eine schematische Schnittansicht des Rollenpakets gemäß 5;
• 7 zeigt eine schematische Schnittansicht einer weiteren Ausführungsform einer Schienenvorrichtung für die Reinigungsanlage gemäß 2; und
• 8 zeigt eine schematische perspektivische Ansicht einer Ausführungsform eines Rollenpakets für die Schienenvorrichtung gemäß 7.

Further advantageous embodiments and aspects of the invention are the subject of the dependent claims and the embodiments of the invention described below. Furthermore, the invention will be explained in more detail by means of preferred embodiments with reference to the attached figures.

• 1A shows a schematic view of an embodiment of an EUV lithography system;
• 1B shows a schematic view of an embodiment of a DUV lithography system;
• 2 shows a schematic plan view of an embodiment of a cleaning system for cleaning components of a lithographic system according to 1A or 1B ;
• 3 shows a schematic sectional view of an embodiment of a rail device for the cleaning system according to 2 ;
• 4 shows the detail view IV according to 3 ;
• 5 shows a schematic perspective view of an embodiment of a roll package for the rail device according to 3 ;
• 6 shows a schematic sectional view of the roll package according to 5 ;
• 7 shows a schematic sectional view of another embodiment of a rail device for the cleaning system according to 2 ; and
• 8th shows a schematic perspective view of an embodiment of a roll package for the rail device according to 7 ,

In the figures, the same or functionally identical elements have been given the same reference numerals, unless stated otherwise. It should also be noted that the illustrations in the figures are not necessarily to scale.

1A shows a schematic view of an EUV lithography system 100A which is a beam shaping and illumination system 102 and a projection system 104 includes. EUV stands for "extreme ultraviolet" (English: extreme ultraviolet, EUV) and denotes a wavelength of working light between 0.1 nm and 30 nm. The beam shaping and illumination system 102 and the projection system 104 are each provided in a vacuum housing, not shown, wherein each vacuum housing is evacuated by means of an evacuation device, not shown. The vacuum housings are surrounded by a machine room, not shown, in which drive devices are provided for the mechanical method or adjustment of optical elements. Furthermore, electrical controls and the like may be provided in this engine room.

The EUV lithography system 100A has an EUV light source 106A on. As an EUV light source 106A For example, a plasma source (or a synchrotron) can be provided, which radiation 108A in the EUV range (extreme ultraviolet range), so for example in the wavelength range of 5 nm to 20 nm emits. In the beam-forming and lighting system 102 becomes the EUV radiation 108A bundled, and the desired operating wavelength is from the EUV radiation 108A filtered out. The from the EUV light source 106A generated EUV radiation 108A has a relatively low transmissivity by air, which is why the beam guiding spaces in the beam-forming and lighting system 102 and in the projection system 104 are evacuated.

This in 1A illustrated beam shaping and illumination system 102 has five mirrors 110 . 112 . 114 . 116 . 118 on. After passing through the beam shaping and lighting system 102 becomes the EUV radiation 108A on a photomask (English: reticle) 120 directed. The photomask 120 is also designed as a reflective optical element and can be outside the systems 102 . 104 be arranged. Next, the EUV radiation 108A by means of a mirror 122 on the photomask 120 be steered. The photomask 120 has a structure which, by means of the projection system 104 reduced to a wafer 124 or the like is mapped.

The projection system 104 (also called projection lens) has six mirrors M1 to M6 for imaging the photomask 120 on the wafer 124 on. It can single mirror M1 to M6 of the projection system 104 symmetrical to an optical axis 126 of the projection system 104 be arranged. It should be noted that the number of mirrors M1 to M6 the EUV lithography system 100A is not limited to the number shown. There may also be more or less mirrors M1 to M6 be provided. Furthermore, the mirrors M1 to M6 usually curved at its front for beam shaping.

1B shows a schematic view of a DUV lithography system 100B which is a beam shaping and illumination system 102 and a projection system 104 includes. DUV stands for "deep ultraviolet" (English: deep ultraviolet, DUV) and refers to a wavelength of working light between 30 nm and 250 nm. The beam shaping and illumination system 102 and the projection system 104 can - as already related to 1A be described - surrounded by a machine room with corresponding drive devices.

The DUV lithography system 100B has a DUV light source 106B on. As a DUV light source 106B For example, an ArF excimer laser can be provided, which radiation 108B in the DUV range at, for example, 193 nm emitted.

This in 1B illustrated beam shaping and illumination system 102 directs the DUV radiation 108B on a photomask 120 , The photomask 120 is designed as a transmissive optical element and can be outside the systems 102 . 104 be arranged. The photomask 120 has a structure which, by means of the projection system 104 reduced to a wafer 124 or the like is mapped.

The projection system 104 has several lenses 128 and / or mirrors 130 for imaging the photomask 120 on the wafer 124 on. This can be individual lenses 128 and / or mirrors 130 of the projection system 104 symmetrical to an optical axis 126 of the projection system 104 be arranged. It should be noted that the number of lenses 128 and mirrors 130 the DUV lithography system 100B is not limited to the number shown. There may also be more or fewer lenses 128 and / or mirrors 130 be provided. Furthermore, the mirrors 130 usually curved at its front for beam shaping.

An air gap between the last lens 128 and the wafer 124 can be through a liquid medium 132 be replaced, which has a refractive index> 1. The liquid medium 132 can be, for example, high purity water. Such a structure is also referred to as immersion lithography and has an increased photolithographic resolution. The medium 132 can also be referred to as immersion liquid.

In the production of a lithography system as explained above 100A . 100B It may be necessary to use the beamforming and lighting system 102 and / or the projection system 104 as a module to undergo a cleaning. For this purpose, cleaning systems with residual gas analysis can be used. For example, you can Frontloader UHV vacuum systems are used. "UHV" stands for ultra-high vacuum.

The beam shaping and lighting system 102 or the projection system 104 may have a mass of 8 t or 15 t. To the beam shaping and lighting system 102 or the projection system 104 into a cleaning system as mentioned above or pull out of this, a rail system can be used, on which the Strahlformungs- and lighting system 102 or the projection system 104 can be placed.

Due to the application in UHV, the usable materials are very limited. To the masses of the beam-forming and lighting system 102 or the projection system 104 To be able to move and minimize particle generation, the rolling resistance of the rail system must be low and plastic deformation of the rail surface by the Hertzian pressure is to be prevented. The surface pressure can be minimized by an adapted geometry selection. The remaining Hertzian pressure must then be absorbed by the components of the rail system, which requires a high hardness.

The occurring loads, namely the voltage peaks in the material occur at a depth of a few tenths of a millimeter. Due to this, a minimum hardening depth of more than 0.5 mm is necessary. A surface hardening of stainless steel with little distortion is not feasible with the asymmetrical geometry of known rails. A process in which steel receives a higher surface hardness due to the diffusion of other substances and no distortion occurs, such as nitriding, for example, is insufficient due to the small layer thickness.

2 shows a schematic plan view of an embodiment of a cleaning system as mentioned above 200 with residual gas analysis, which is suitable, the beam forming and lighting system 102 or the projection system 104 to pick up and clean. Instead of the cleaning system 200 can - as previously mentioned - for example, a measuring system can be provided. In the 2 is merely an example of the projection system 104 shown. The cleaning system 200 includes a receiving area 202 which is suitable, the beam-forming and lighting system 102 or the projection system 104 take.

The cleaning system 200 includes a rail system 204 which meets the above requirements and does not have the aforementioned disadvantages. With the help of the rail system 204 is the beamforming and lighting system 102 or the projection system 104 in a direction of insertion e in the recording area 202 can be moved in and opposite to the insertion direction e in a single direction A pulled out of this. The rail system 204 includes a first rail device 206 and a second rail device 208 , The rail devices 206 . 208 are parallel to and spaced from each other. There are at least two rail devices 206 . 208 intended. The rail devices 206 . 208 each extend along a longitudinal direction L , The longitudinal direction L can with the insertion direction e or the extension direction A to match.

3 shows a schematic sectional view of an embodiment of the first rail device 206 , 4 shows the detail view IV according to the 3 , 5 shows a schematic perspective view of an embodiment of a roll package 210 for the first rail device 206 , 6 shows a schematic sectional view of the roll package 210 , Below is on the 3 to 6 simultaneously referred to.

The first rail device 206 includes next to the roll package 210 a first guide rail 212 on which the roll package 210 can roll. The guide rail 212 extends in the longitudinal direction L , The guide rail 212 includes a tread element 214 and a support element 216 which is the tread element 214 wearing. The support element 216 may be a double T-carrier. Thus, the functions support structure and tread of the guide rail 212 to two separate components, namely the tread element 214 and the support element 216 , separated.

The support element 216 is uncured and thus maintains its toughness. For example, the support element 216 made of stainless steel. The support element 216 includes a web section 218 that between two border sections 220 . 222 is arranged, resulting in the double-T shape. The bridge section 218 may include cooling channels, so-called deep hole drilling in an embodiment, not shown. With the help of these cooling channels can better tempering or faster cooling of the component to be cleaned, for example, the projection system 104 to be achieved in a vacuum. The edge section 222 may have a V-shaped geometry and the tread element 214 at least partially record. In particular, the edge portion 222 two V-shaped contact surfaces 224 . 226 have on which the tread element 214 rests. With the help of fasteners 228 , in particular screws, is the tread element 214 with the support element 216 firmly connected.

In the longitudinal direction L considered can be the tread element 214 have a length of about 0.5 to 1.5 m. In principle, however, the length is arbitrary and can also be more than 1.5 m. In the longitudinal direction L can be any number of tread elements 214 be arranged one behind the other. An overall length of the guide rail 212 can be 5 m. This is achieved by the succession of several tread elements 214 reached. The tread element 214 can be made of hardened stainless steel. The tread element 214 includes two V-shaped treads 230 . 232 ( 4 ) on which in the operation of the rail system 204 the roll package 210 rolls. The geometry of the treads 230 . 232 is chosen so that the Hertzian pressure is minimized.

To obtain an approximately rotationally symmetric geometry, the tread element comprises 214 two of the treads 230 . 232 facing away chamfers 234 . 236 , With the chamfers 234 . 236 lies the tread element 214 on the bearing surfaces 224 . 226 on. Because of this approximately rotationally symmetrical geometry of the tread element 214 can be minimized distortion of the same during curing. Due to the small length of the tread element 214 For example, 0.5 to 1.5 m, a slight distortion during curing can be achieved. Furthermore, the chamfers allow 234 . 236 the adjustment of the tread elements 214 to each other in the support element 216 , By placing spacers or spacers (not shown), a further adjustment is possible if required.

The edge section 220 of the support element 216 can be fastened via supports, not shown, to a supporting structure, for example on a hall floor. Below the edge section 220 can be a spacer or spacer 238 be provided. For aligning the guide rail 212 can on any support such spacers 238 be used. These can be ground in as needed. Thus, a tilt and a height offset can be compensated.

That in the 5 and 6 shown roll package 210 includes several, for example, four, individually suspended and sprung roles 240 . 242 . 244 . 246 that puts the load evenly on the guide rail 212 distribute and allow the crossing of track interruptions. Every role 240 . 242 . 244 . 246 has two V-shaped treads 248 . 250 ( 3 ) on the treads 230 . 232 of the tread element 214 roll. The roles 240 . 242 . 244 . 246 can be made of hardened stainless steel. Due to the V-shaped treads 230 . 232 . 248 . 250 is a side guide of the rollers 240 . 242 . 244 . 246 on the tread element 214 guaranteed. The roles 240 . 242 . 244 . 246 are thus perpendicular to the longitudinal direction L on the tread element 214 guided.

Every role 240 . 242 . 244 . 246 is with the help of an axis 252 in a U-shaped receiving element 254 rotatably mounted. The roles 240 . 242 . 244 . 246 are on their respective axis 252 roller bearings. In order to be able to transfer the high Hertzian stresses, full ceramic bearings (not shown) are preferably used. Due to their high hardness, dry running without much abrasion is possible.

The recording elements 254 the roles 240 . 242 . 244 . 246 are in a common housing 256 of the roll package 210 added. Between the recording elements 254 and the housing 256 are spring elements 258 . 260 ( 3 ) is provided, the one spring travel of the receiving elements 254 opposite the housing 256 of at least 3 to 4 mm. The spring elements 258 . 260 can be so-called screw-plate springs. The spring elements 258 . 260 are in the receptacles 254 added. For this purpose, they have corresponding recesses 262 . 264 on.

With the help of guide pins 266 . 268 , in particular so-called sword pins, are the receiving elements 254 the roles 240 . 242 . 244 . 246 in the case 256 perpendicular to the longitudinal direction L linearly displaceable. The guide pins 266 . 268 are by the spring elements 258 . 260 guided and firmly with the respective receiving element 254 connected. The guide pins 266 . 268 prevent tilting of the receiving elements 254 in the case 256 , For the guide pins 266 . 268 are in the case 256 corresponding recesses 270 . 272 intended.

With the help of two clamping covers 274 . 276 becomes the case 256 closed and the spring elements 258 . 260 are brought under bias. The clamping lid 274 . 276 are with the help of fasteners 278 ( 5 ), in particular by means of screws, with the housing 256 firmly connected. Front and back covers the case 256 two final lids 280 . 282 ,

7 shows a schematic sectional view of an embodiment of the second rail device 208 , 8th shows a schematic perspective view of an embodiment of a roll package 210 for the second rail device 208 , Below is on the 7 and 8th simultaneously referred to.

The basic structure of the second rail device 208 corresponds to the first rail device 206 , Therefore, hereinafter, only differences between the rail devices 206 . 208 received. The second rail device 208 is different from the first rail device 206 essentially by another geometry of the tread element 214 and the roles 240 . 242 . 244 . 246 , Identical components are in the 7 and 8th denoted by the same reference numerals.

The second rail device 208 includes a second guide rail 284 with a tread element 214 and a support element 216 , The tread element 214 However, there are no two V-shaped treads 230 . 232 but only a flat tread 286 on. Accordingly, the roles include 240 . 242 . 244 . 246 no two V-shaped treads 248 . 250 but a convex tread 288 , The housing 256 is with the help of a one-piece clamping lid 290 locked.

Because of this different geometry of the tread element 214 and the roles 240 . 242 . 244 . 246 are the roles 240 . 242 . 244 . 246 perpendicular to the longitudinal direction L not on the tread element 214 guided. That is, the roles 240 . 242 . 244 . 246 can be perpendicular to the longitudinal direction L on the tread element 214 slide. Thus, the second rail device 208 as a floating bearing and the first rail device 206 as a fixed bearing of the rail system 204 act.

Although the present invention has been described with reference to embodiments, it is variously modifiable.

LIST OF REFERENCE NUMBERS

100A

EUV lithography system

100B

DUV lithography system

102

Beam shaping and lighting system

104

projection system

106A

EUV-light source

106B

DUV light source

108A

EUV radiation

108B

DUV radiation

110

mirror

112

mirror

114

mirror

116

mirror

118

mirror

120

photomask

122

mirror

124

wafer

126

optical axis

128

lens

130

mirror

132

medium

200

purifier

202

reception area

204

rail system

206

rail construction

208

rail construction

210

role package

212

guide rail

214

Tread member

216

supporting member

218

web section

220

edge section

222

edge section

224

bearing surface

226

bearing surface

228

fastener

230

tread

232

tread

234

chamfer

236

chamfer

238

spacer

240

role

242

role

244

role

246

role

248

tread

250

tread

252

axis

254

receiving element

256

casing

258

spring element

260

spring element

262

recess

264

recess

266

guide pin

268

guide pin

270

recess

272

recess

274

clamping cover

276

clamping cover

278

fastener

280

cover

282

cover

284

guide rail

286

tread

288

tread

290

clamping cover

A

extraction direction

e

insertion direction

L

longitudinal direction

M1

mirror

M2

mirror

M3

mirror

M4

mirror

M5

mirror

M6

mirror

Claims (15)

Rail apparatus (206, 208) for moving components (102, 104) of a lithography system (100A, 100B) a guide rail (212, 284), and a roller package (210) with rotatably mounted rollers (240, 242, 244, 246), wherein the guide rail (212, 284) comprises a tread element (214) on which the rollers (240, 242) in operation of the rail device (206, 208) , 244, 246), and a support member (216) carrying the tread member (214), and wherein the tread member (214) and the support member (216) are positively connected with each other. Rail device after Claim 1 wherein the support element (216) is made of an uncured steel alloy, in particular of uncured stainless steel, and wherein the tread element (214) is made of a hardened steel alloy, in particular of hardened stainless steel. Rail device after Claim 1 or 2 wherein the tread element (214) has two V-shaped treads (230, 232) or a planar tread (286). Rail device after Claim 3 , wherein the tread element (214) facing away from the V-shaped running surfaces (230, 232) has two V-shaped chamfers (234, 236). Rail device after Claim 4 , wherein the support element (216) has two V-shaped arranged bearing surfaces (224, 226) on which the chamfers (234, 236) rest. Rail device according to one of Claims 1 - 5 wherein the tread element (214) has an octagonal or a rectangular cross-sectional geometry. Rail device according to one of Claims 1 - 6 wherein the rollers (240, 242, 244, 246) in the roller package (210) are mounted individually resiliently. Rail device after Claim 7 wherein each roller (240, 242, 244, 246) is associated with a receiving element (254) in or on which the respective roller (240, 242, 244, 246) is rotatably mounted, and wherein each receiving element (254) in one Housing (256) of the roll package (210) is mounted individually resiliently. Rail device after Claim 8 wherein each receiving element (254) is assigned at least one spring element (258, 260) which is arranged between the respective receiving element (254) and the housing (256). Rail device after Claim 8 or 9 wherein each receiving element (254) is associated with at least one guide pin (266, 268) which guides the respective receiving element (254) linearly in or on the housing (256). Rail device according to one of Claims 1 - 10 wherein the rollers (240, 242, 244, 246) each have two V-shaped treads (248, 250) or a crowned tread (288). Rail device according to one of Claims 1 - 11 , further comprising a plurality of tread elements (214) arranged one behind the other in a longitudinal direction (L) of the rail device (206, 208), the support element (216) supporting the plurality of tread elements (214). Rail device according to one of Claims 1 - 12 , further comprising a spacer (238), in particular a spacer, which is arranged on an edge portion (220) of the support element (216) facing away from the tread element (214). Rail system (204) with at least one rail device (206, 208) according to one of Claims 1 - 13 , Rail system after Claim 14 , further comprising a first rail device (206) and a second rail device (208), wherein the first rail device (206) acts as a fixed bearing of the rail system (204), and wherein the second rail device (208) functions as a floating bearing of the rail system (204).

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