KR20210149250A - Cryopump - Google Patents

Abstract

The low-temperature cryopanel unit of the cryopump includes two cryopanel members 62 disposed on both sides of the low-temperature cooling stage with the central axis of the cryopump interposed therebetween. Each cryopanel member 62 has a bow-shaped flat portion 75 having an arcuate portion 78 and a string 79, and is integrally formed with the bow-shaped flat portion 75 to form a bow at a part of the string 79. A first bent portion 76 connected to the shape flat portion 75 is provided. The bow-shaped flat portion 75 is thermally coupled to the low-temperature cooling stage through the first bent portion 76 . The shape of the remainder of the string of the bow-shaped flat portion 75 of each cryopanel member 62 is determined so that the two cryopanel members 62 can be interchanged with each other without interfering with the refrigerator.

Description

Cryopump {CRYOPUMP}

The present invention relates to a cryopump.

A cryopump is a vacuum pump that traps and exhausts gas molecules by condensation or adsorption in a cryopanel cooled to a cryogenic temperature. A cryopump is generally used to realize a clean vacuum environment required for a semiconductor circuit manufacturing process and the like.

Patent Document 1: Japanese Patent Application Laid-Open No. 7-35041

One of the exemplary objects of one aspect of the present invention is to reduce the manufacturing cost of the cryopump.

According to an aspect of the present invention, the cryopump includes a refrigerator having a high-temperature cooling stage and a low-temperature cooling stage, and a cryopump central shaft that is thermally coupled to the high-temperature cooling stage and passes through the center of the cryopump intake port. a radiation shield extending in the direction and surrounding the low-temperature cooling stage, and a low-temperature cryopanel unit thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage. The low-temperature cryopanel unit is disposed at a height between an upper end and a lower end of the low-temperature cooling stage in the direction of the central axis of the cryopump, the cryopump central axis interposed therebetween. and two cryopanel members disposed on both sides of the Each cryopanel member has an arc-shaped flat portion having an arc portion and a chord, and the bow-shaped flat portion is integrally formed with the bow-shaped flat portion to form a portion of the chord with the bow-shaped flat portion. and a first bent portion connected to. The bow-shaped flat portion is thermally coupled to the low-temperature cooling stage through the first bent portion. The arc portion of the bow-shaped flat portion defines an outer edge of the cryopanel member when viewed from the central axis of the cryopump. The shape of the remainder of the string of the bow-shaped flat portion of each cryopanel member is determined so that the two cryopanel members are interchangeable with each other without interfering with the refrigerator.

According to an aspect of the present invention, the cryopump includes a refrigerator having a high-temperature cooling stage and a low-temperature cooling stage, and a cryopump central shaft that is thermally coupled to the high-temperature cooling stage and passes through the center of the cryopump intake port. a radiation shield extending in the direction and surrounding the low-temperature cooling stage, a low-temperature cryopanel part thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage, wherein the cryopump central axis is interposed between and a low-temperature cryopanel unit having two cryopanel members disposed on both sides of the low-temperature cooling stage, and two mounting surfaces respectively corresponding to the two cryopanel members. Each cryopanel member includes a bow-shaped flat portion having an arcuate portion and a string, and a first bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion at a portion of the string. The first bent portion is attached to a corresponding mounting surface. The bow-shaped flat portion is thermally coupled to the low-temperature cooling stage through the first bent portion. The shape of the remainder of the string of the bow-shaped flat portion of each cryopanel member is determined so that the two cryopanel members are interchangeable with each other without interfering with the refrigerator. Each cryopanel member includes a second bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion in at least a portion of the remainder of the string. The second bent portion is disposed away from the mounting surface in the direction of the string.

However, it is also effective as an aspect of this invention that the components and expressions of this invention are mutually substituted among methods, apparatuses, systems, and the like.

According to the present invention, the manufacturing cost of the cryopump can be reduced.

1 is a side cross-sectional view schematically showing a cryopump according to an embodiment.
FIG. 2 is a top view schematically illustrating the cryopump shown in FIG. 1 .
3 is a perspective view schematically showing a part of a low-temperature cryopanel part of the cryopump according to the embodiment.
4 is a perspective view schematically showing a part of a low-temperature cryopanel part of the cryopump according to the embodiment.
5 is a perspective view schematically showing a part of a low-temperature cryopanel unit of the cryopump according to the embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing this invention is demonstrated in detail, referring drawings. In the description and drawings, the same or equivalent components, members, and processes are denoted by the same reference numerals, and overlapping explanations are omitted as appropriate. The scale and shape of each part shown are set for convenience in order to facilitate the explanation, and are not interpreted limitedly unless otherwise noted. Embodiment is an illustration, and does not limit the scope of the present invention. All the features or combinations thereof described in the embodiments are not necessarily essential to the invention.

1 is a side cross-sectional view schematically showing a cryopump 10 according to an embodiment. FIG. 2 is a top view schematically showing the cryopump 10 shown in FIG. 1 . 1 shows a cross section including a cryopump central axis C indicated by a dashed-dotted line. However, for easy understanding, in FIG. 1 , the low-temperature cryopanel part of the cryopump 10 shows a side surface, not a cross-section. Fig. 2 is a view seen from the arrow direction along the line B-B. 3 and 4 are perspective views schematically showing a part of the low-temperature cryopanel part of the cryopump 10 according to the embodiment.

The cryopump 10 is, for example, mounted in a vacuum chamber of an ion implantation apparatus, a sputtering apparatus, a deposition apparatus, or other vacuum process apparatus, to increase the degree of vacuum inside the vacuum chamber to a level required for a desired vacuum process. used The cryopump 10 has an intake port 12 for receiving a gas to be exhausted from the vacuum chamber. Gas enters the internal space 14 of the cryopump 10 through the intake port 12 .

The cryopump 10 may be intended to be installed and used in the vacuum chamber in the illustrated direction, that is, in a posture in which the intake port 12 is directed upward. However, the posture of the cryopump 10 is not limited thereto, and the cryopump 10 may be installed in the vacuum chamber in a different direction.

However, hereinafter, the terms "axial direction" and "diameter direction" are sometimes used to indicate the positional relationship of the components of the cryopump 10 in a way that is easy to understand. The axial direction indicates a direction passing through the intake port 12 (in FIG. 1 , a direction along the cryopump central axis C passing through the center of the intake port 12 ), and the radial direction indicates a direction along the intake port 12 . The direction (direction perpendicular to the central axis C) is indicated. For convenience, a thing relatively close to the intake port 12 with respect to the axial direction is called "upper side", and a thing relatively far from the intake port 12 is called "lower side" in some cases. That is, a thing relatively far from the bottom of the cryopump 10 is called "upper side", and a thing relatively close to the bottom of the cryopump 10 is called "lower side" in some cases. Regarding the radial direction, a thing close to the center of the intake port 12 (central axis C in FIG. 1 ) may be called "inside", and a thing close to the peripheral edge of the intake port 12 may be called "outside". However, this expression is not related to the arrangement when the cryopump 10 is mounted in the vacuum chamber. For example, the cryopump 10 may be mounted in the vacuum chamber with the intake port 12 downward in the vertical direction.

In addition, the direction surrounding an axial direction may be called "circumferential direction". The circumferential direction is the second direction along the intake port 12 and is a tangential direction orthogonal to the radial direction.

The cryopump 10 includes a refrigerator 16 , a first stage cryopanel 18 , a second stage cryopanel assembly 20 , and a cryopump housing 70 . The first stage cryopanel 18 may also be referred to as a high temperature cryopanel unit or a 100K unit. The second stage cryopanel assembly 20 may also be referred to as a low-temperature cryopanel unit or a 10K unit.

The refrigerator 16 is a cryogenic refrigerator, such as a Gifford McMahon type refrigerator (so-called GM refrigerator), for example. The refrigerator 16 is a two-stage refrigerator. For this reason, the refrigerator 16 is equipped with the 1st cooling stage 22 and the 2nd cooling stage 24. As shown in FIG. The refrigerator 16 is configured to cool the first cooling stage 22 to the first cooling temperature, and to cool the second cooling stage 24 to the second cooling temperature. The second cooling temperature is lower than the first cooling temperature. For example, the first cooling stage 22 is cooled to about 65K ~ 120K, preferably 80K ~ 100K, the second cooling stage 24 is cooled to about 10K ~ 20K.

In addition, the refrigerator 16 structurally supports the second cooling stage 24 to the first cooling stage 22 , and structurally supports the first cooling stage 22 to the room temperature part 26 of the refrigerator 16 . and a refrigerator structural part 21 supported by the . Accordingly, the refrigerator structural unit 21 includes a first cylinder 23 and a second cylinder 25 extending coaxially in the radial direction. The first cylinder 23 connects the room temperature part 26 of the refrigerator 16 to the first cooling stage 22 . The second cylinder 25 connects the first cooling stage 22 to the second cooling stage 24 . The room temperature section 26, the first cylinder 23, the first cooling stage 22, the second cylinder 25, and the second cooling stage 24 are arranged in a straight line in this order.

Inside each of the first cylinder 23 and the second cylinder 25, a first displacer and a second displacer (not shown) are arranged reciprocally. The first displacer and the second displacer include a first regenerator and a second regenerator (not shown), respectively. Moreover, the room temperature part 26 has a drive mechanism (not shown) for reciprocating the 1st displacer and the 2nd displacer. The drive mechanism includes a flow path switching mechanism for switching the flow path of the working gas so as to periodically repeat the supply and discharge of the working gas (eg, helium) to the inside of the refrigerator 16 .

The first cooling stage 22 is provided at the first low-temperature stage of the refrigerator 16 . The first cooling stage 22 is a member that covers the end of the first cylinder 23 on the opposite side to the room temperature portion 26 and surrounds the first expansion space of the working gas. The first expansion space is formed between the first cylinder 23 and the first displacer in the inside of the first cylinder 23, and is a variable volume whose volume changes according to the reciprocating movement of the first displacer. The first cooling stage 22 is made of a metal material having a higher thermal conductivity than the first cylinder 23 . For example, the first cooling stage 22 is formed of copper, and the first cylinder 23 is formed of stainless steel.

The second cooling stage 24 is provided at the second stage low-temperature stage of the refrigerator 16 . The second cooling stage 24 is a member that covers the end of the second cylinder 25 on the opposite side to the room temperature portion 26 and surrounds the second expansion space of the working gas. The second expansion space is formed between the second cylinder 25 and the second displacer in the inside of the second cylinder 25 and is a variable volume whose volume changes according to the reciprocating movement of the second displacer. The second cooling stage 24 is made of a metal material having a higher thermal conductivity than the second cylinder 25 . The second cooling stage 24 is made of copper, and the second cylinder 25 is made of stainless steel. In FIG. 1 , a boundary 24b between the second cooling stage 24 and the second cylinder 25 is shown.

The refrigerator 16 is connected to a compressor (not shown) of the working gas. The refrigerator 16 cools the first cooling stage 22 and the second cooling stage 24 by expanding the working gas pressurized by the compressor from the inside. The expanded working gas is returned to the compressor and pressurized again. The refrigerator 16 generates cooling by repeating a thermal cycle including supply/discharge of working gas and reciprocating movement of the first and second displacers synchronized thereto.

The illustrated cryopump 10 is a so-called horizontal cryopump. The horizontal cryopump is generally a cryopump in which the refrigerator 16 is arranged to intersect the central axis C of the cryopump 10 (usually orthogonal to it). The first cooling stage 22 and the second cooling stage 24 of the refrigerator 16 are in a direction perpendicular to the cryopump central axis C (a horizontal direction in FIG. 1 , and the central axis of the refrigerator 16 ). (D) direction).

The first stage cryopanel 18 includes a radiation shield 30 and an inlet cryopanel 32 , and surrounds the second stage cryopanel assembly 20 . The first-stage cryopanel 18 is provided to protect the second-stage cryopanel assembly 20 from radiant heat external to the cryopump 10 or from the cryopump housing 70 . to be. The first stage cryopanel 18 is thermally coupled to the first cooling stage 22 . Accordingly, the first stage cryopanel 18 is cooled to the first cooling temperature. The first-stage cryopanel 18 has a gap between the first-stage cryopanel assembly 20 and the second-stage cryopanel assembly 20 , and the first-stage cryopanel 18 is in contact with the second-stage cryopanel assembly 20 . not doing

The radiation shield 30 is provided to protect the second stage cryopanel assembly 20 from radiant heat of the cryopump housing 70 . The radiation shield 30 is located between the cryopump housing 70 and the second stage cryopanel assembly 20 and surrounds the second stage cryopanel assembly 20 . The radiation shield 30 has a shield main opening 34 for receiving gas into the internal space 14 from the outside of the cryopump 10 . The shield main opening 34 is located in the intake port 12 .

The radiation shield 30 has a shield front end 36 defining the shield main opening 34, a shield bottom portion 38 located on the opposite side to the shield main opening 34, and a shield front end 36 at the shield bottom portion. A shield side portion (40) connected to (38) is provided. The shield front end 36 forms a part of the shield side portion 40 . The shield side portion 40 extends from the shield front end 36 to the opposite side to the shield main opening 34 in the axial direction, and extends to surround the second cooling stage 24 in the circumferential direction. The radiation shield 30 has a cylindrical shape (for example, a cylinder) in which the shield bottom 38 is closed, and is formed in a cup shape. An annular gap 42 is formed between the shield side portion 40 and the second stage cryopanel assembly 20 .

However, the shield bottom portion 38 may be a member separate from the shield side portion 40 . For example, the shield bottom portion 38 may be a flat disk having substantially the same diameter as the shield side portion 40 , or may be attached to the shield side portion 40 from the side opposite to the shield main opening 34 . In addition, at least a part of the shield bottom 38 may be open. For example, the radiation shield 30 may not be blocked by the shield bottom 38 . That is, both ends of the shield side part 40 may be open.

The shield side portion 40 has a shield side opening 44 into which the cryocooler structure portion 21 is inserted. A second cooling stage 24 and a second cylinder 25 are inserted into the radiation shield 30 from the outside of the radiation shield 30 through the shield side opening 44 . The shield-side opening 44 is a mounting hole formed in the shield-side portion 40, and has a circular shape, for example. The first cooling stage 22 is disposed outside the radiation shield 30 .

The shield side portion (40) is provided with a mounting seat (46) of the refrigerator (16). The mounting sheet 46 is a flat portion for mounting the first cooling stage 22 to the radiation shield 30 , and is slightly dented when viewed from the outside of the radiation shield 30 . The mounting sheet (46) forms the outer periphery of the shield side opening (44). The mounting seat 46 is closer to the shield bottom 38 than to the shield front end 36 in the axial direction. As the first cooling stage 22 is mounted on the mounting sheet 46 , the radiation shield 30 is thermally coupled to the first cooling stage 22 .

As such, instead of directly mounting the radiation shield 30 to the first cooling stage 22 , in one embodiment, the radiation shield 30 is connected to the first cooling stage 22 through an additional heat transfer member. They may be thermally coupled. The heat transfer member may be, for example, a hollow short cylinder having flanges at both ends. The heat transfer member may be fixed to the mounting sheet 46 by a flange at one end and to the first cooling stage 22 by a flange at the other end. The heat transfer member may surround the refrigerator structural part 21 and may extend from the first cooling stage 22 to the radiation shield 30 . The shield side portion 40 may include such a heat transfer member.

In the illustrated embodiment, the radiation shield 30 is configured as an integral tube. Alternatively, the radiation shield 30 may be configured to have a general shape as a whole by a plurality of parts. These several components may have a space|interval mutually and may be arrange|positioned. For example, the radiation shield 30 may be divided into two parts in the axial direction. In this case, the upper portion of the radiation shield 30 is a cylinder with both ends open, and includes a shield front end 36 and a first portion of the shield side portion 40 . The lower portion of the radiation shield 30 has an open upper end and a closed lower end, and includes a second portion of the shield side portion 40 and a shield bottom portion 38 . As described above, the lower portion of the radiation shield 30 may not have the shield bottom portion 38, and the barrel may be open at both ends. A slit extending in the circumferential direction is formed between the first portion and the second portion of the shield side portion 40 . This slit may be at least a part of the shield side portion 40 . Alternatively, the shield-side opening 44 may have its upper half formed as the first portion of the shield-side portion 40 and the lower half formed as the second portion of the shield-side portion 40 .

The inlet cryopanel 32 is provided in the shield main opening 34 to protect the second stage cryopanel assembly 20 from radiant heat from an external heat source of the cryopump 10 . The heat source external to the cryopump 10 is, for example, a heat source in a vacuum chamber in which the cryopump 10 is mounted. The inlet cryopanel 32 may restrict the ingress of gas molecules as well as radiant heat. The inlet cryopanel 32 occupies a part of the opening area of the shield main opening 34 so as to limit the gas inflow into the inner space 14 through the shield main opening 34 to a desired amount. An annular open area 48 is formed between the inlet cryopanel 32 and the shield front end 36 .

The inlet cryopanel 32 includes a louver part 50 and a louver mounting member 52 for mounting the louver part 50 to the front end of the shield 36 . The louver mounting member 52 is a rod-shaped member spanning the shield front end 36 along the diameter of the shield main opening 34 . The inlet cryopanel 32 is thermally coupled to the first cooling stage 22 through the louver mounting member 52 and the radiation shield 30 .

The louver portion 50 has a plurality of right plates each extending in a straight line in the first direction in the shield main opening 34 . The plurality of right plates are arranged in a second direction perpendicular to the first direction in the shield main opening 34 . A plurality of right plates are arranged parallel to each other, and each right plate is disposed inclined with respect to the opening surface. As shown, the right plate on one side and the right plate on the other side are inclined in opposite directions with respect to the central axis C. The plurality of right plates cover the second-stage cryopanel assembly 20 located immediately below it (that is, so that the second-stage cryopanel assembly 20 is not visible from the outside of the cryopump 10 ). , are densely arranged in the second direction. The plurality of right plates have different lengths in the first direction so as to form a circle as a whole by the arrangement. The louver mounting member 52 extends in the second direction.

Accordingly, the gas to be exhausted by the cryopump 10 enters the internal space 14 from the outside of the cryopump 10 through the gap or the open area 48 between the right plates of the louver part 50 . do.

The inlet cryopanel 32 may have other shapes. For example, the louver part 50 may have a some annular right plate arrange|positioned concentrically. Alternatively, the inlet cryopanel 32 may be a single plate-shaped member.

The second stage cryopanel assembly 20 is mounted on the second cooling stage 24 so as to surround the second cooling stage 24 . Accordingly, the second stage cryopanel assembly 20 is thermally coupled to the second cooling stage 24 , and the second stage cryopanel assembly 20 is cooled to the second cooling temperature. The second stage cryopanel assembly 20 is surrounded by the shield side portion 40 together with the second cooling stage 24 .

The second stage cryopanel assembly 20 includes a top cryopanel 60 facing the shield main opening 34 , a plurality (two in this example) cryopanel members 62 , and a cryopanel A mounting member (64) is provided.

Also, as shown in FIG. 1 , the cryopump 10 includes a cryopanel positioning member 67 . The heat transfer unit thermally coupling the second stage cryopanel assembly 20 to the second cooling stage 24 includes a cryopanel mounting member 64 and a cryopanel positioning member 67 .

Since an annular gap 42 is formed between the top cryopanel 60 and the cryopanel member 62 and the shield side portion 40 , the top cryopanel 60 and the cryopanel member 62 . are both not in contact with the radiation shield (30). The cryopanel member 62 is covered by the top cryopanel 60 .

The top cryopanel 60 is a portion closest to the inlet cryopanel 32 of the second stage cryopanel assembly 20 . The top cryopanel 60 is disposed between the shield main opening 34 or the inlet cryopanel 32 and the refrigerator 16 in the axial direction. The top cryopanel 60 is located in the center of the internal space 14 of the cryopump 10 in the axial direction. For this reason, the main accommodating space 65 of the condensation layer is formed widely between the front surface of the top cryopanel 60 and the inlet cryopanel 32 . The main accommodating space 65 of the condensing layer occupies the upper half of the inner space 14 .

The top cryopanel 60 is a substantially flat cryopanel arranged perpendicular to the axial direction. That is, the top cryopanel 60 extends in the radial direction and the circumferential direction. As shown in FIG. 2 , the top cryopanel 60 is a disk-shaped panel having a larger dimension (eg, projected area) than the louver part 50 . However, the relationship between the dimensions of the top cryopanel 60 and the louver part 50 is not limited thereto, and the top cryopanel 60 may be smaller, or both may have substantially the same dimensions.

The top cryopanel 60 is disposed so as to form a gap region 66 between the top cryopanel 60 and the refrigerator structural unit 21 . The gap region 66 is an empty space formed between the rear surface of the top cryopanel 60 and the second cylinder 25 in the axial direction.

The cryopanel member 62 is provided with an adsorbent 74 such as activated carbon. The adsorbent 74 is adhered to the back surface of the cryopanel member 62 , for example. It is intended that the front surface of the cryopanel member 62 functions as a condensation surface and the rear surface functions as an adsorption surface. The adsorbent 74 may be provided on the entire surface of the cryopanel member 62 . Similarly, the top cryopanel 60 may have the adsorbent 74 on the front surface and/or the rear surface thereof. Alternatively, the top cryopanel 60 may not include the adsorbent 74 .

The two cryopanel members 62 are disposed on both sides of the second cooling stage 24 with the cryopump central axis C interposed therebetween. The cryopanel member 62 is disposed along a plane perpendicular to the cryopump central axis C. For easy understanding, the cryopanel member 62 and the cryopanel mounting member 64 are indicated by broken lines in FIG. 2 .

The two cryopanel members 62 are arranged at a height between the upper end and the lower end of the second cooling stage 24 in the direction of the cryopump central axis C. The second cooling stage 24 includes a flange portion 24a at an end in a direction perpendicular to the cryopump central axis C (direction of the central axis D of the refrigerator 16 ). The upper end and lower end of the second cooling stage 24 in the direction of the cryopump central axis C are defined by the flange portion 24a. That is, the two cryopanel members 62 are disposed at a height between the upper end and the lower end of the flange portion 24a of the second cooling stage 24 in the direction of the cryopump central axis C. has been The two cryopanel members 62 are arranged at the same height. The boundary 24b between the 2nd cooling stage 24 and the 2nd cylinder 25 shown in FIG. 1 is another one of the 2nd cooling stage 24 in the direction of the central axis D of the refrigerator 16. An end (that is, an end opposite to the flange portion 24a) is defined.

FIG. 3 shows two cryopanel members 62 and a cryopanel mounting member 64 , and FIG. 4 shows one cryopanel member 62 .

The two cryopanel members 62 are designed as the same component. The two cryopanel members 62 have the same shape and are formed of the same material. The cryopanel member 62 has a shape of a bow, a meniscus, or a semicircle. The cryopanel member 62 may be formed of, for example, a metal material having high thermal conductivity such as copper, and may be coated with a plating layer such as nickel, for example.

The cryopanel mounting member 64 has two mounting surfaces 68 respectively corresponding to the two cryopanel members 62 . The cryopanel mounting member 64 is a bracket having a rectangular inverted U-shape, and is for heat transfer from the second cooling stage 24 to the top cryopanel 60 and the cryopanel member 62 . It is also an electric heating plate. The two mounting surfaces 68 correspond to the two side surfaces of the cryopanel mounting member 64 . The cryopanel member 62 is mounted to the corresponding mounting surface 68 using a fastening member 87 (eg, a rivet).

A top cryopanel 60 is mounted on the upper surface 69 of the cryopanel mounting member 64 connecting these mounting surfaces 68 . The mounting surface 68 extends perpendicularly to the upper surface 69 downward from both sides of the upper surface 69 .

The second cooling stage 24 and the cryopanel positioning member 67 are inserted into the inside of the cryopanel mounting member 64 in the direction of the central axis D of the refrigerator 16, and the second cooling stage ( 24) is mounted to the cryopanel mounting member 64 via the cryopanel positioning member 67. The cryopanel positioning member 67 is mounted on the upper surface 69 of the cryopanel mounting member 64 (however, opposite to the top cryopanel 60 ). The top cryopanel 60 , the cryopanel mounting member 64 , and the cryopanel positioning member 67 are integrated with the second cooling stage 24 using a fastening member (eg, bolt). is fixed to

Each cryopanel member 62 includes a bow-shaped flat portion 75 , a first bent portion 76 , and a second bent portion 77 . Each cryopanel member 62 is formed of a single metal plate. By press-working, for example, on one flat metal plate, the first bent portion 76 and the second bent portion 77 are integrated with the bow-shaped flat portion 75, so that one cryopanel member ( 62) is made. The adsorbent 74 is provided on the bow-shaped flat portion 75 . The adsorbent 74 is not provided in the 1st bent part 76 and the 2nd bent part 77.

The bow-shaped flat portion 75 has an arc portion 78 and a string 79 . The string 79 is a single straight line connecting the both ends of the arc part 78 . The arc portion 78 and the chord 79 are in a plane perpendicular to the cryopump central axis C, and when viewed from the cryopump central axis C, outline the cryopanel member 62 . decide The arc portion 78 defines the outer edge of the cryopanel member 62 , and the string 79 defines the inner edge of the cryopanel member 62 . In the cryopanel member 62 , the arc part 78 is close to the shield side part 40 of the radiation shield 30 , and the string 79 is the second cooling stage 24 and the second of the refrigerator 16 . It is arranged so as to be close to the cylinder 25 . The chords 79 are parallel to the axial direction D of the chiller 16 , and half of the chords 79 extend along the second cooling stage 24 and the second cylinder 25 of the chiller 16 , The other half extends toward the shield side portion 40 beyond the second cooling stage 24 .

The entire bow-shaped flat portion 75 is flat, and in particular, the outer edge portion including the arc portion 78 is flat. In this respect, the cryopanel member 62 has a shape different from that of a typical cryopanel having a conical object inclined surface at the outer periphery.

The first bent portion 76 is connected to the bow-shaped flat portion 75 at a part of the string 79 , specifically, at the central portion of the string 79 . The first bent part 76 is provided as a fastening part for fastening the cryopanel member 62 to the cryopanel mounting member 64 . The first bent portion 76 is mounted on the corresponding mounting surface 68 of the cryopanel mounting member 64 . The bow-shaped flat portion 75 is thermally coupled to the second cooling stage 24 through the first bent portion 76 . The first bent portion 76 is a rectangular portion that forms an angle (for example, a right angle) with respect to the bow-shaped flat portion 75 . The first bent portion 76 is upright with respect to the bow-shaped flat portion 75 . The first bent portion 76 is long and slender in the direction of the string 79 , and the width of the first bent portion 76 in the direction of the string 79 is equal to the mounting surface of the cryopanel mounting member 64 ( 68) is almost equal to the width of

The first bent portion 76 is bent upward with respect to the bow-shaped flat portion 75 , and has a fastening hole 88 through which the fastening member 87 passes. The fastening hole 88 is disposed between the string 79 and the upper side 76a of the first bent portion 76 so as to be adjacent to each other on the upper side. The fastening hole 88 is formed above the midline 89 between the string 79 and the upper side 76a of the first bent portion 76 .

In this way, since the distance between the fastening hole 88 and the bow-shaped flat part 75 becomes large, it becomes easy for the operator to handle the tool (for example, a rivet gun) used for fastening, and workability in the manufacturing process This is improved. Further, according to this configuration, when the cryopanel member 62 is mounted to the cryopanel mounting member 64 , the gravity applied to the bow-shaped flat portion 75 of the cryopanel member 62 is 1 Acts as a moment for pressing the bent portion 76 against the mounting surface 68 . For this reason, compared to other mounting configurations (for example, when the bending part for mounting is bent downward with respect to the cryopanel member and fastened to the mounting surface near the lower edge of the bent part), it has a bow shape with respect to the mounting surface 68. The inclination of the flat portion 75 is suppressed.

The second bent portion 77 includes at least a part of the remainder of the string 79 (that is, the portion where the first bent portion 76 is not provided), specifically, at both ends of the string 79, a bow-shaped flat portion ( 75) is connected. The second bent portion 77 is disposed away from the mounting surface 68 of the cryopanel mounting member 64 in the direction of the string 79 . The second bent portion 77 is outside with respect to the mounting surface 68 . The second bent portion 77 is an edge portion forming an angle (for example, a right angle) with respect to the bow-shaped flat portion 75 , and is elongated in the direction of the string 79 . The second bent portion 77 is upright with respect to the bow-shaped flat portion 75 .

The second bent portion 77 is provided as a rigidity reinforcing portion of the cryopanel member 62 . The second bent portion 77 can suppress deformation of the bow-shaped flat portion 75 . In particular, when the cryopanel member 62 is relatively large, compared to the width of the mounting surface 68 (that is, the length of the central portion of the string 79 ), the length of the string 79 that is outside the mounting surface 68 . The length of the end portion is increased, and as a result, both ends of the bow-shaped flat portion 75 are liable to be deformed such as bending or tilting due to the action of gravity. By providing the second bent portion 77 , deformation can be suppressed even when the cryopanel member 62 is relatively large.

The second bent portion 77 is connected to the bow-shaped flat portion 75 over the entire length of the remainder of the string 79 . Accordingly, the second bent portion 77 is continuous with the first bent portion 76 in the direction of the string 79 . Since the second bent portion 77 extends over the entire length of the remainder of the string 79 , deformation of the cryopanel member 62 can be more effectively suppressed.

The second bent portion 77 is bent upward with respect to the bow-shaped flat portion 75 similarly to the first bent portion 76 . The height of the second bent portion 77 from the bow-shaped flat portion 75 is lower than the height of the first bent portion 76 from the bow-shaped flat portion 75 . In this way, it becomes difficult for the second bent part 77 to interfere with the surrounding components (eg, other cryopanel disposed adjacently in the direction of the cryopump central axis C). Further, it is easy to densely arrange the plurality of cryopanel members 62 in the axial direction. For example, the height of the second bent portion 77 may be lower than the midline 89 between the string 79 and the upper side 76a of the first bent portion 76 .

However, the second bent portion 77 may be bent in a direction or angle different from that of the first bent portion 76 . For example, the first bent portion 76 may be bent upward, and the second bent portion 77 may be bent downward. The first bent portion 76 may be bent perpendicularly to the bow-shaped flat portion 75 , and the second bent portion 77 may be bent at an inclination angle with respect to the bow-shaped flat portion 75 .

The second bent portion 77 may be provided only in a part of the remainder of the string 79 (that is, the portion where the first bent portion 76 is not provided).

As shown in FIG. 2 , when viewed in the direction of the cryopump central axis C, the two cryopanel members 62 have a symmetrical axis between the two cryopanel members 62 (the central axis D of the refrigerator 16 ). are arranged symmetrically to each other. The arc portions 78 of the two cryopanel members 62 are on the same circumference with the cryopump central axis C as the center. In addition, each cryopanel member 62 passes through the midpoint of the string 79 (or the cryopump central axis C) and has a line E perpendicular to the string 79 as the axis of symmetry. Thus, it has a linearly symmetrical shape.

The shape of the remainder of the string 79 of the bow-shaped flat portion 75 of each cryopanel member 62 (that is, the portion where the first bent portion 76 is not provided) is determined by the refrigerator 16 (for example, It is determined so that the two cryopanel members 62 are interchangeable with each other without interfering with the second cooling stage 24 and the second cylinder 25).

As one exemplary configuration, the interval 90 between the two cryopanel members 62 is a second cooling between the two cryopanel members 62 at any position in the direction of the chords 79 . It has a size that allows the stage 24 to be inserted. The distance 90 between the two cryopanel members 62 is constant over the entire length of the chord in the chord direction.

In this way, the two cryopanel members 62 are compatible. One cryopanel member 62 can be mounted on either of the two mounting surfaces 68 of the cryopanel mounting member 64 . When one cryopanel member 62 is mounted on one mounting surface 68 and when mounted on the other mounting surface 68, the arc portion 78 of the cryopanel member 62 has the same circumference. is on top In addition, when one cryopanel member 62 is mounted on one mounting surface 68 and when mounted on the other mounting surface 68, the chords 79 of the cryopanel member 62 are It is located equidistant to the central axis (D) of (16). The cryopanel member 62 can be mounted on either of the two mounting surfaces 68 without interfering with the second cooling stage 24 and the second cylinder 25 of the refrigerator 16 .

1 , the cryopanel positioning member 67 is fixed to the flange portion 24a of the second cooling stage 24 and supported by the second cooling stage 24 . The cryopanel positioning member 67 is formed in an inverted L-shape. The longitudinal side of the cryopanel positioning member 67 is attached to the flange portion 24a by an appropriate fastening member such as bolts, for example. The upper side portion 67a of the cryopanel positioning member 67 extends in the direction of the central axis D of the refrigerator 16 from the flange portion 24a of the second cooling stage 24 . The upper side portion 67a extends toward the first cooling stage 22 along the second cooling stage 24 or the second cylinder 25 in the cryopanel mounting member 64 .

The second cooling stage 24 is deviated from the cryopump central axis C in the direction of the central axis D of the refrigerator 16 . The distance from the mounting sheet 46 of the radiation shield 30 to the flange portion 24a of the second cooling stage 24 in the direction of the central axis D of the refrigerator 16 is the It is shorter than the distance from the mounting sheet 46 of the radiation shield 30 to the cryopump central axis C in the direction of the central axis D (conversely, it may be longer). For this reason, if the second-stage cryopanel assembly 20 is disposed directly above the second cooling stage 24 , the second-stage cryopanel assembly 20 is positioned on the central axis D of the refrigerator 16 . deviate from the cryopump central axis (C) in the direction of

By the way, the cryopanel positioning member 67 includes two cryopanel members ( 62) is supported. The cryopanel positioning member 67 is formed so that the cryopanel mounting member 64 can be disposed at an appropriate position for positioning the cryopanel member 62 with respect to the cryopump central axis C. has been In this way, the second stage cryopanel assembly 20 is positioned on the cryopump central axis (C).

By using the cryopanel positioning member 67, the restriction on the length of the refrigerator 16 in the direction of the central axis D is relieved. As a result, instead of a refrigerator designed exclusively for the cryopump 10 , an existing refrigerator may be employed. This may help to reduce the manufacturing cost of the cryopump 10 .

However, for positioning of the second stage cryopanel assembly 20 with respect to the cryopump central axis C, the upper edge 67a of the cryopanel positioning member 67 is different from that shown in FIG. 1 . Conversely, from the flange portion 24a of the second cooling stage 24 , it may extend away from the second cylinder 25 in the direction of the central axis D of the refrigerator 16 . For the cryopump 10 having a large-diameter intake port 12, a cryopanel positioning member 67 having such a shape may be suitable.

The cryopump housing 70 is a case of the cryopump 10 accommodating the first stage cryopanel 18 , the second stage cryopanel assembly 20 , and the refrigerator 16 , and has an internal space. It is a vacuum container configured to maintain the vacuum tightness of (14). The cryopump housing 70 includes the first stage cryopanel 18 and the refrigerator structural part 21 in a non-contact manner. The cryopump housing 70 is attached to the room temperature part 26 of the refrigerator 16 .

The intake port 12 is defined by the front end of the cryopump housing 70 . The cryopump housing 70 includes an intake flange 72 extending radially outward from its front end. The inlet flange 72 is provided over the entire circumference of the cryopump housing 70 . The cryopump 10 is mounted in a vacuum chamber to be evacuated using an intake flange 72 .

The cryopump 10 includes a gas flow adjusting member 80 configured to deflect the flow of gas flowing in from the shield main opening 34 from the refrigerator structural part 21 . The gas flow adjusting member 80 is configured to deflect the gas flow flowing into the main accommodation space 65 through the louver part 50 or the open area 48 from the second cylinder 25 . The gas flow adjusting member 80 may be a gas flow deflecting member or a gas flow reflecting member disposed above and adjacent to the refrigerator structural member 21 or the second cylinder 25 . The gas flow adjusting member 80 is, for example, a single flat plate, but may be curved.

The gas flow adjusting member 80 is disposed adjacent to the refrigerator structural unit 21 so as to be non-contact with both of the second cooling stage 24 and the second stage cryopanel assembly 20 . The gas flow adjusting member 80 is disposed along the second cylinder 25 so as to be non-contact with any of the second cooling stage 24 , the second stage cryopanel assembly 20 , and the second cylinder 25 . has been A clearance 86 is formed between the gas flow adjusting member 80 and the second cylinder 25 . In this way, the gas flow adjusting member 80 is thermally and structurally separated from the portion cooled to the second cooling temperature and the structural portion supporting the portion.

The gas flow adjusting member 80 extends from the shield side portion 40 toward the gap region 66 and is thermally coupled to the first cooling stage 22 . The gas flow adjusting member (80) is supported by the shield side portion (40). Accordingly, the gas flow adjusting member 80 is cooled to the first cooling temperature.

The gas flow adjusting member 80 extends circumferentially along the shield side portion 40 so as to at least partially close the annular gap 42 . The gas flow adjusting member 80 is provided locally at the same position as the shield side opening 44 in the circumferential direction. The gas flow adjusting member 80 has a rectangular shape when viewed from above. However, the gas flow adjusting member 80 may be longer in the circumferential direction, for example, along the shield side portion 40 over the entire circumference.

Since the base end 82 (that is, the portion mounted on the shield side portion 40) of the gas flow adjusting member 80 is located on the outside of the louver portion 50 in the radial direction, as shown in FIG. 2, the intake port ( 12) is exposed. The proximal end 82 of the gas flow adjusting member 80 is visible from the outside of the cryopump 10 through the open area 48 and the annular gap 42 . The base end 82 does not overlap the top cryopanel 60 when viewed in the axial direction.

The tip 84 of the gas flow adjusting member 80 enters the gap region 66 and is covered with the top cryopanel 60 . This tip 84 is disposed between the outer peripheral end of the top cryopanel 60 and the central axis C in the radial direction of the cryopump. Since the tip 84 does not reach the second cooling stage 24 , the gas flow adjusting member 80 is not in contact with the second cooling stage 24 as described above.

In this way, as the gas flow adjusting member 80 is inserted into the gap region 66 between the top cryopanel 60 and the second cylinder 25 , the inlet of the gap region 66 is narrowed. Accordingly, it is possible to reduce the inflow of gas from the main accommodating space 65 to the gap region 66 .

The operation of the cryopump 10 having the above configuration will be described below. When the cryopump 10 is operated, first, the inside of the vacuum chamber is rough pumped to about 1 Pa with another suitable roughing pump before the operation. After that, the cryopump 10 is operated. The first cooling stage 22 and the second cooling stage 24 are cooled to a first cooling temperature and a second cooling temperature, respectively, by the driving of the refrigerator 16 . Accordingly, the first-stage cryopanel 18 and the second-stage cryopanel assembly 20 thermally coupled thereto are also cooled to the first cooling temperature and the second cooling temperature, respectively. Since the gas flow adjusting member 80 is thermally coupled to the first cooling stage 22, it is cooled to the first cooling temperature.

The inlet cryopanel 32 cools the gas flying from the vacuum chamber toward the cryopump 10 . On the surface of the inlet cryopanel 32 , a ^{gas having a sufficiently low vapor pressure (eg, 10 −8} Pa or less) at the first cooling temperature is condensed. This base|substrate may be called a 1st-class base|substrate. The first-class gas is, for example, water vapor. In this way, the inlet cryopanel 32 can exhaust the first type gas. A portion of the gas whose vapor pressure is not sufficiently low at the first cooling temperature passes through the louver part 50 or the open area 48 and enters the main accommodation space 65 . Alternatively, another part of the gas is reflected from the inlet cryopanel 32 and does not enter the main accommodation space 65 .

The gas entering the main accommodation space 65 is cooled by the second stage cryopanel assembly 20 . On the surface of the second stage cryopanel assembly 20 , a ^{gas having a sufficiently low vapor pressure (eg, 10 −8} Pa or less) at the second cooling temperature is condensed. This base|substrate may be called a 2nd-class base|substrate. The second type gas is, for example, argon. In this way, the second stage cryopanel assembly 20 can exhaust the second type gas. Since it directly faces the main accommodating space 65 , the condensed layer of the second type gas may grow largely on the front surface of the top cryopanel 60 . However, the second type gas is a gas without condensing at the first cooling temperature.

The gas whose vapor pressure is not sufficiently low at the second cooling temperature is adsorbed to the adsorbent of the second stage cryopanel assembly 20 . This base|substrate may be called a 3rd-class base|substrate. The third gas is, for example, hydrogen. In this way, the second stage cryopanel assembly 20 can exhaust the third type gas. Accordingly, the cryopump 10 exhausts various gases by condensing or adsorption, and can reach a desired level of vacuum in the vacuum chamber.

As described above, the two cryopanel members 62 are compatible. The two cryopanel members 62 are at least partially identical in shape. Accordingly, at least a part of the manufacturing process of the second stage cryopanel assembly 20 can be commonized, and the manufacturing cost of the cryopump 10 can be reduced. In particular, in this embodiment, the two cryopanel members 62 are designed as the same component. The two cryopanel members are manufactured by the same manufacturing process. The number of parts for the cryopump is reduced. The manufacturing cost is further reduced.

This idea can be extended to the cryopanel members 62 having different diameters, and a part of their manufacturing processes can be made common. In cryopanel members having different diameters, the first bent portion 76 (fastening portion) has a common shape, and the arc portion 78 of the bow-shaped flat portion 75 is flattened, so that the press-working mold can be common. have. Pressing of the cryopanel member 62 having a smaller diameter can be performed using a mold designed for press working (eg, bending, punching) of the cryopanel member 62 having a larger diameter. have. Since molds are generally relatively expensive, common use of molds is effective in reducing manufacturing costs. It is advantageous for a manufacturer to provide a plurality of types of cryopumps 10 having different diameters of the intake ports 12 .

As described above, the cryopump 10 is provided with a gas flow adjusting member 80 . Since the gas flow adjusting member 80 covers the second cylinder 25 , the second cylinder 25 is not exposed to the shield main opening 34 . The gas flow adjusting member 80 may deflect the flow of the second type gas from the main accommodation space 65 toward the second cylinder 25 in another direction. For this reason, although the second cylinder 25 has a temperature distribution from the first cooling temperature to the second cooling temperature on its surface, the second type gas condensed on the surface portion of the second cooling temperature or a temperature close to the second cooling temperature is almost None or none at all In addition, since the gas flow adjusting member 80 has the first cooling temperature, the second type gas is not condensed on the surface of the gas flow adjusting member 80 .

A portion of the gas entering the main accommodation space 65 may be reflected by the gas flow adjusting member 80 . At least a portion of the reflected gas is directed to the second stage cryopanel assembly 20 . Alternatively, a portion of the reflected gas may be directed to the radiation shield 30 or the inlet cryopanel 32 , where it is reflected back and directed to the second stage cryopanel assembly 20 . In this way, the second stage cryopanel assembly 20 can exhaust the second type gas by condensation and exhaust the third type gas by adsorption.

A cryopump generally includes two types of cryopanels having different temperatures. Gas condenses in the cryopanel at low temperature. As the cryopump is used, a condensed layer grows on the low-temperature cryopanel. Similarly, a condensation layer may grow on the structure supporting the low-temperature cryopanel. The grown condensed layer may one day come into contact with the high-temperature cryopanel. Then, at the contact portion between the high-temperature cryopanel and the condensing layer, the gas is vaporized again and discharged to the surroundings. Outgassing from the condensate layer can prevent the cryopump from fulfilling its role. Therefore, the gas occlusion amount at the time of contact can provide the maximum occlusion amount of the cryopump.

However, according to the cryopump 10 according to the embodiment, the gas flow adjusting member 80 relieves or reduces the growth of the condensed layer at a location where the portion at the first cooling temperature and the portion at the second cooling temperature approach each other. can be prevented Accordingly, the cryopump 10 can relieve or prevent the contact between the condensed layer and the portion at the first cooling temperature, and furthermore, the regasification of the condensed layer. As a result, a large amount of the second type gas can be condensed on the entire surface of the top cryopanel 60 in the main accommodation space 65 . Accordingly, the gas storage amount of the cryopump 10 can be improved.

As mentioned above, this invention was demonstrated based on embodiment. The present invention is not limited to the above embodiment, and various design changes are possible, and it is understood by those skilled in the art that various modifications are possible, and that such modifications are also within the scope of the present invention.

For example, as shown in FIG. 5 , a plurality of cryopanel members 62 may be mounted on each mounting surface 68 of the cryopanel mounting member 64 . A plurality of (two in this example) cryopanel members 62 are arranged on each mounting surface 68 in the direction of the cryopump central axis. In this way, the plurality of cryopanel members 62 may be disposed on each of both sides of the second cooling stage 24 of the refrigerator 16 .

In the above, the horizontal cryopump 10 has been described as an example. However, the present invention is also applicable to a so-called vertical cryopump. The vertical cryopump generally refers to a cryopump in which the refrigerator 16 is disposed along the cryopump central axis C.

The shape of the cryopanel member 62 is not limited to the above, and may have other shapes. The bow-shaped flat portion 75 , the first bent portion 76 , and/or the second bent portion 77 does not need to be completely flat as a whole. For example, the bow-shaped flat part 75 may have an inclined surface, a concave part, or a convex part in any one site|part (for example, the site|part except the circular arc part 78). In addition, it is not essential that the arc part 78 of the cryopanel member 62 is a strictly circular arc. Similarly, it is not essential that the chords 79 of the cryopanel member 62 are strictly straight. The bow-shaped flat portion 75 , the first bent portion 76 , and/or the second bent portion 77 may have an opening such as a hole or a slit.

In the embodiment described above, the mounting sheet 46 of the radiation shield 30 is formed on the lower half of the radiation shield 30 . For this reason, the second cooling stage 24 is relatively close to the shield bottom 38 in the direction of the cryopump central axis C. However, the arrangement of the second cooling stage 24 is not essential. A mounting sheet 46 of the radiation shield 30 is formed on the upper half of the radiation shield 30 , and the second cooling stage 24 has a shield front end 36 in the direction of the cryopump central axis C. It may be placed close to In addition, the mounting sheet 46 of the radiation shield 30 is formed in the central portion of the shield side portion 40 in the direction of the cryopump central axis C, and the second cooling stage 24 is the cryopump center It may be arranged at the center of the radiation shield 30 in the direction of the axis C.

Embodiment of this invention can also be expressed as follows.

1. A refrigerator having a high-temperature cooling stage and a low-temperature cooling stage;

a radiation shield thermally coupled to the high-temperature cooling stage, extending in the direction of the cryopump central axis passing through the center of the cryopump intake port, and surrounding the low-temperature cooling stage;

A low-temperature cryopanel part thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage, the height between the top and bottom of the low-temperature cooling stage in the direction of the cryopump central axis a low-temperature cryopanel unit having two cryopanel members disposed on both sides of the low-temperature cooling stage with the cryopump central axis interposed therebetween;

Each cryopanel member includes a bow-shaped flat portion having an arc portion and a string, and a first bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion at a portion of the string, the bow The flat shape portion is thermally coupled to the low-temperature cooling stage through the first bent portion, and the arc portion of the bow-shaped flat portion determines the outer edge of the cryopanel member when viewed in the direction of the cryopump central axis,

The cryopump according to claim 1, wherein the shape of the remainder of the string of the bow-shaped flat portion of each cryopanel member is determined so that the two cryopanel members are interchangeable with each other without interfering with the refrigerator.

2. Further comprising two mounting surfaces respectively corresponding to the two cryopanel members, wherein the first bent part is mounted on the corresponding mounting surfaces,

Each cryopanel member includes a second bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion in at least a portion of the remaining portion of the string, wherein the second bent portion is configured to be formed in a direction of the string The cryopump according to Embodiment 1, wherein the cryopump is disposed away from the mounting surface.

3. The cryostat according to Embodiment 2, wherein the second bent portion is connected to the bow-shaped flat portion over the entire length of the remainder of the string and is continuous with the first bent portion in the direction of the string. oppump.

4. The cryopump according to any one of Embodiments 1 to 3, wherein the two cryopanel members are designed as the same part.

5. The distance between the two cryopanel members is determined to be such that the low-temperature cooling stage can be inserted between the two cryopanel members at any position in the direction of the strings. The cryopump according to any one of Embodiments 1 to 4.

6. The cryopump according to Embodiment 5, wherein an interval between the two cryopanel members is constant over the entire length of the string in the direction of the string.

7. The first bent part is bent upward with respect to the bow-shaped flat part, and has a hole through which the fastening member passes,

The cryopump according to any one of Embodiments 1 to 6, wherein the hole is disposed close to the upper edge between the string and the upper edge of the first bent portion.

8. The high-temperature cooling stage and the low-temperature cooling stage of the refrigerator are arranged in a direction perpendicular to the central axis of the cryopump,

The cryopump further includes a cryopanel positioning member supported by the low-temperature cooling stage and extending in a direction perpendicular to the central axis of the cryopump from the low-temperature cooling stage,

The cryopanel positioning member supports the two cryopanel members so as to position the center of the arc portion of the bow-shaped flat portion of each cryopanel member on the cryopump central axis. The cryopump according to any one of 1 to 7.

9. A refrigerator having a high-temperature cooling stage and a low-temperature cooling stage;

a radiation shield thermally coupled to the high-temperature cooling stage, extending in the direction of the cryopump central axis passing through the center of the cryopump intake port, and surrounding the low-temperature cooling stage;

A low-temperature cryopanel part thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage, two cryos arranged on both sides of the low-temperature cooling stage with the central axis of the cryopump interposed therebetween. A low-temperature cryopanel unit having a panel member, and

and two mounting surfaces respectively corresponding to the two cryopanel members,

Each cryopanel member includes a bow-shaped flat portion having an arc portion and a string, and a first bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion at a portion of the string, 1 bent portion is mounted on the corresponding mounting surface, the bow-shaped flat portion is thermally coupled to the low temperature cooling stage through the first bent portion,

The shape of the remainder of the string of the bow-shaped flat portion of each cryopanel member is determined so that the two cryopanel members are interchangeable with each other without interfering with the refrigerator;

Each cryopanel member includes a second bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion in at least a portion of the remaining portion of the string, wherein the second bent portion is configured in a direction of the string A cryopump, characterized in that it is disposed away from the mounting surface in the.

10. It is characterized in that it is disposed on both sides of the low-temperature cooling stage with the cryopump central axis interposed therebetween at a height position between the upper end and the lower end of the cryopump cooling stage in the direction of the cryopump central axis. The cryopump according to Embodiment 9.

11. The cryopump according to the 9th or 10th embodiment, wherein the arc portion of the bow-shaped flat portion defines an outer edge of the cryopanel member when viewed in the direction of the central axis of the cryopump.

12. The second bent portion is connected to the bow-shaped flat portion over the entire length of the remainder of the string, and is continuous with the first bent portion in the direction of the string The cryopump as described in any one.

13. The cryopump according to any one of Embodiments 9 to 12, wherein the two cryopanel members are designed as the same part.

14. The distance between the two cryopanel members is determined to be such that the low-temperature cooling stage can be inserted between the two cryopanel members at any position in the direction of the strings. The cryopump according to any one of Embodiments 9 to 13.

15. The cryopump according to Embodiment 14, wherein an interval between the two cryopanel members is constant over the entire length of the string in the direction of the string.

16. The first bent part is bent upward with respect to the bow-shaped flat part, and has a hole through which the fastening member passes;

The cryopump according to any one of Embodiments 9 to 15, wherein the hole is disposed close to the upper edge between the string and the upper edge of the first bent portion.

17. The high-temperature cooling stage and the low-temperature cooling stage of the refrigerator are arranged in a direction perpendicular to the central axis of the cryopump,

The cryopump further includes a cryopanel positioning member supported by the low-temperature cooling stage and extending in a direction perpendicular to the central axis of the cryopump from the low-temperature cooling stage,

The cryopanel positioning member supports the two cryopanel members so as to position the center of the arc portion of the bow-shaped flat portion of each cryopanel member on the cryopump central axis. The cryopump according to any one of 9 to 16.

10 Liopump
12 intake
16 Freezer
24 2nd cooling stage
30 radiation shield
62 cryopanel member
67 Cryopanel positioning member
68 mounting surface
75 bow flat part
76 first bend
77 second bend
78 Auxiliary Department
C Cryopump central shaft
79 strings
87 Fastening member
88 fastening hole

Claims (10)

A refrigerator having a high-temperature cooling stage and a low-temperature cooling stage;
a radiation shield thermally coupled to the high temperature cooling stage, extending in the direction of the cryopump central axis passing through the center of the cryopump intake port, and surrounding the low temperature cooling stage;
A low-temperature cryopanel part thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage, the height between the top and bottom of the low-temperature cooling stage in the direction of the cryopump central axis a low-temperature cryopanel unit having two cryopanel members disposed on both sides of the low-temperature cooling stage with the cryopump central axis interposed therebetween;
and two mounting surfaces respectively corresponding to the two cryopanel members;
Each cryopanel member,
A bow-shaped flat portion having an arc portion and a string;
a first bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion at a portion of the string and mounted on the corresponding mounting surface;
and a second bent portion integrally formed with the bow-shaped flat portion and connected to the bow-shaped flat portion in at least a portion of the remainder of the string,
A height of the second bent portion from the bow-shaped flat portion is lower than a height of the first bent portion from the bow-shaped flat portion. According to claim 1,
A height of the second bent portion is lower than a midline between the string and an upper side of the first bent portion. 3. The method of claim 1 or 2,
In each of the two cryopanel members, when the first bent portion of the cryopanel member is mounted on one mounting surface and when mounted on the other mounting surface, the arc portion of the cryopanel member is on the same circumference. A cryopump, characterized in that there is. 3. The method of claim 1 or 2,
Further comprising an inlet cryopanel provided at the cryopump intake port,
The inlet cryopanel includes a louver portion each having a plurality of right plates extending in a straight line in the first direction. 5. The method of claim 4,
The plurality of right plates are arranged parallel to each other in a second direction perpendicular to the first direction. 5. The method of claim 4,
The plurality of right plates may have different lengths in the first direction so as to form a circle as a whole by arrangement thereof. 5. The method of claim 4,
The low-temperature cryopanel unit further includes a top cryopanel disposed on a side of the cryopump intake port rather than the two cryopanel members,
A main accommodating space of the condensation layer is formed between the front surface of the top cryopanel and the inlet cryopanel, and the main accommodating space occupies an upper half of the internal space of the cryopump. cryopump. 8. The method of claim 7,
The top cryopanel is a cryopump, characterized in that it is a disk-shaped panel having a larger dimension than the inlet cryopanel. A refrigerator having a high-temperature cooling stage and a low-temperature cooling stage;
a radiation shield thermally coupled to the high temperature cooling stage, extending in the direction of the cryopump central axis passing through the center of the cryopump intake port, and surrounding the low temperature cooling stage;
A low-temperature cryopanel part thermally coupled to the low-temperature cooling stage and surrounded by the radiation shield together with the low-temperature cooling stage, the height between the top and bottom of the low-temperature cooling stage in the direction of the cryopump central axis a low-temperature cryopanel unit having two cryopanel members disposed on both sides of the low-temperature cooling stage with the cryopump central axis interposed therebetween;
and an inlet cryopanel provided in the cryopump intake port,
The low-temperature cryopanel unit further includes a top cryopanel disposed on a side of the cryopump intake port rather than the two cryopanel members,
A main receiving space of the condensation layer is formed between the front surface of the top cryopanel and the inlet cryopanel, and the main receiving space occupies an upper half of the internal space of the cryopump. oppump. 10. The method of any one of claims 1, 2 and 9,
A gas flow adjusting member disposed between the top cryopanel of the low-temperature cryopanel part and the two cryopanel members so as to be non-contact with both the low-temperature cooling stage and the low-temperature cryopanel part, characterized in that it further comprises: cryopump.

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