JP7196763B2 - turbomolecular pump and mass spectrometer - Google Patents

Description

The present invention relates to turbomolecular pumps and mass spectrometers.

In a mass spectrometer such as a gas chromatograph mass spectrometer or an inductively coupled plasma mass spectrometer, ionized ions of a sample are sent from an ion sending unit to a mass spectrometer provided with a quadrupole mass spectrometer and an ion detector. It is introduced and analyzed (see Patent Document 1, for example). The first chamber provided with the mass analysis section and the second chamber provided with the ion delivery section communicate with each other through an ion passage hole. In an analyzer having two chambers, the following two types of evacuation of the first and second chambers are known. In the first example analyzer, the first and second chambers are evacuated by separate vacuum pumps. A second example is an analyzer such as that described in US Pat. Evacuate the second chamber.

JP 2008-95504 A

The turbomolecular pump described in Patent Document 1 is the second example, and has a first intake port connected to the first chamber and a second intake port connected to the second chamber. This turbo-molecular pump is a vertical turbo with two turbine stages on the same rotor shaft arranged coaxially with the first inlet, and the first inlet is provided directly above the upstream first turbine stage. It is a molecular pump. A second inlet connected to the second chamber is arranged in parallel with the first inlet and communicates with an opening formed in the side of the pump housing between the first and second turbine stages by a pipe section. there is Therefore, there is a problem that the exhaust speed at the second intake port is suppressed due to the influence of the conductance of the piping portion.

A turbomolecular pump according to a preferred aspect of the present invention comprises a pump casing having a flange portion, a first casing portion and a second casing portion, a first intake port and a second intake port provided side by side on the flange portion, and the a first accommodation space provided in one casing portion, the first accommodation space including a first region corresponding to the first air inlet and a second region corresponding to the second air inlet; a second housing space provided in a casing portion; a first pump stage provided facing the first intake port in the first region of the first housing space; a second pump stage provided coaxially with the first pump stage and spaced apart from the first pump stage by a predetermined distance; an exhaust junction formed between the first pump stage and the gas from the first intake port and the gas from the second intake port passing through the second region, wherein the A partition wall is formed in the flange portion to separate the first intake port and the second intake port, and the partition wall is not formed in the first casing portion. The opposing area is exposed to the second area.
In a further preferred aspect, the first pump stage includes a pump rotor section comprising a plurality of rotor blade stages, a pump stator section comprising a plurality of stator blade stages and a plurality of spacers alternately laminated, and the spacer has a grip portion that grips the stator blade stage together with the adjacent spacer so as to sandwich the stator blade stage, and a fitting portion that extends from the radial outer periphery of the grip portion and covers the radial outer periphery of the stator blade stage. , the radial outer peripheral surface of the spacer is exposed to the second region.
In a further preferred embodiment, the fitting portion has a radial thickness smaller than that of the gripping portion, and the fitting portion has an outer diameter smaller than that of the partition wall. It is
In a further preferred aspect, the stator blade stage is configured by joining two halved stator blades, and the outer peripheral surface of the two halved stator blades other than the joining portion faces the second region. and the joint of the two stator blade halves does not face the second region.
In a further preferred aspect, the first pump stage includes: a pump rotor section comprising a plurality of rotor blade stages; a pump stator section comprising a plurality of stator blade stages and a plurality of spacers alternately laminated; and a shielding member disposed on the radially outer peripheral side and covering the radially outer peripheral side of the stator blade stage and the radially outer peripheral side of the spacer, wherein the outer diameter of the shielding member is set smaller than the outer diameter of the partition wall. It is
In a further preferred embodiment, C is the conductance related to the reverse flow of gas from the outer peripheral side of the stator blade stage gripped by the spacer into the first pump stage, S is the exhaust speed at the first intake port, and S is the first pump stage. is Kt, C<(1/Kt)S is satisfied at each stator blade stage of the first pump stage.
In a further preferred aspect, the spacer is made of a material having a higher tensile strength than an aluminum-based material.
In a further preferred aspect, the shielding member is made of a material having a higher tensile strength than an aluminum-based material.
A mass spectrometer according to a preferred embodiment of the present invention includes a first differential pumping chamber containing a mass spectrometer and a second differential pumping chamber containing an ion sending unit for sending an ionized sample to the mass spectrometer. and the turbomolecular pump, wherein the first intake of the turbomolecular pump is connected to the first differential pumping chamber, and the second intake of the turbomolecular pump is connected to the second differential pumping chamber. be.

According to the present invention, in a vertical turbo-molecular pump having two inlets, it is possible to improve the pumping speed of the second inlet.

FIG. 1 is a diagram showing one embodiment of a turbomolecular pump according to the present invention. FIG. 2 is a cross-sectional view of the pump casing. 3(a) is a view taken along the line A in FIG. 2, and FIG. 3(b) is a cross-sectional view taken along the line BB in FIG. 4 is a cross-sectional view taken along line CC of FIG. 2. FIG. FIG. 5 is a diagram showing a comparative example. FIG. 6 is a diagram for explaining the configuration of the first stator section and its arrangement within the pump casing. FIG. 7 is a diagram illustrating the effect of reverse flow in the first pump stage. FIG. 8 is a diagram for explaining the relationship between stator blades and spacers. FIG. 9 is a diagram showing Modification 1. FIG. FIG. 10 is a diagram showing Modification 2. As shown in FIG. FIG. 11 is a schematic diagram showing the basic configuration of a gas chromatograph mass spectrometer. FIG. 12 is a schematic diagram showing the basic configuration of an inductively coupled plasma mass spectrometer.

Embodiments for carrying out the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing an embodiment of a turbomolecular pump 1 according to the present invention. The turbomolecular pump 1 includes a first intake port 101 for evacuating the first chamber and a second intake port 102 for evacuating the second chamber different from the first chamber. A pump rotor PR is provided inside the pump casing 10 in which the first intake port 101 and the second intake port 102 are formed. The pump rotor PR has a rotating shaft 20 and a first pump rotor portion 21 , a second pump rotor portion 22 and a third pump rotor portion 23 fixed to the rotating shaft 20 .

Further, inside the pump casing 10, there are a first stator portion 31 that forms a first pump stage PS1 together with the first pump rotor portion 21, and a second stator portion 31 that forms a second pump stage PS2 together with the second pump rotor portion 22. A portion 32 and a third stator portion 33 which together with the third pump rotor portion 23 constitute a third pump stage PS3 are provided.

The first stator portion 31 and the second stator portion 32 are arranged with a predetermined gap in the extending direction of the rotating shaft 20 by a spacer 312c. In other words, a spacer 312 c is provided between the first pump rotor portion 21 and the second pump rotor portion 22 . A cylindrical space formed inside the spacer 312c is called an exhaust passage portion (exhaust junction portion) 34. As shown in FIG. The exhaust passage portion 34 is a first area 104S1 of the first accommodation space 101s, which will be described later.

A first chamber connected to the first inlet 101 is evacuated by first through third pump stages PS1-PS3. A second chamber connected to the second inlet 102 is evacuated by second and third pump stages PS2, PS3. The gas exhausted from the second chamber and flowing into the second intake port 102 is configured to join with the airflow from the first intake port 101 exhausted from the first pump rotor portion 21 in the exhaust passage portion 34 . there is This point will be explained in detail later.

The first pump rotor portion 21 is provided with a plurality of rotor blade stages 211 in which turbine blades are formed in the axial direction. The first stator section 31 is formed by alternately stacking a plurality of stator blade stages 311 each having turbine blades and spacers 312a and 312b. there is The multiple stages of stator blade stages 311 are arranged alternately in the axial direction with respect to the rotor blade stages 211 .

The second pump rotor portion 22 is provided with a plurality of rotor blade stages 221 in which turbine blades are formed in the axial direction. The second stator section 32 is formed by alternately stacking a plurality of stator blade stages 321 having turbine blades and spacers 312d. there is

The third pump rotor portion 23 is provided with two cylindrical portions 231 and 232 arranged concentrically. The third stator portion 33 is provided with two stators 331 and 332 arranged concentrically. Stator 331 is arranged on the outer peripheral side of cylindrical portion 231 , and stator 332 is arranged between cylindrical portion 231 and cylindrical portion 232 . For example, the third pump rotor portion 23 constitutes a thread groove pump, and thread grooves are formed in the facing surfaces of the stators 331 and 332 or the cylindrical portions 231 and 232 .

The rotary shaft 20 of the pump rotor PR is supported at its upper end by a magnetic bearing 40 using permanent magnets 41 and 42 and by a ball bearing 50 at its lower end. A permanent magnet 41 is fixed to the rotating shaft 20 and a permanent magnet 42 is fixed to the holder 12 . The holder 12 is fixed to the pump casing 10 via a support member 13 . The holder 12 is provided with a ball bearing 51 that limits whirling of the upper end portion of the rotating shaft 20 . The rotating shaft 20 is rotationally driven by a motor 60 . A motor rotor 61 of the motor 60 is provided on the rotating shaft 20 , and a motor stator 62 of the motor 60 is provided on the base 11 . A ball bearing 50 supporting the rotating shaft 20 is held by a holder 14 fixed to the base 11 .

The gas that has flowed in from the first intake port 101 is sequentially exhausted by the first pump stage PS1, the second pump stage PS2 and the third pump stage PS3, and is discharged from the exhaust port 15. FIG. Also, the gas that has flowed in from the second intake port 102 flows into the exhaust passage portion 34 through the opening 3120 of the exhaust passage portion 34, that is, the opening 3120 formed in the spacer 312c, and flows into the second pump stage PS2 and the third pump stage PS2. It is sequentially evacuated by pump stage PS3 and discharged from exhaust port 15 .

2 to 4 are diagrams for explaining the shape of the pump casing 10. FIG. FIG. 2 is a cross-sectional view of the pump casing 10. As shown in FIG. FIG. 3 shows an A arrow view and a BB sectional view of FIG. 4 is a cross-sectional view taken along line CC of FIG. 2. FIG.

As shown in FIG. 2, the pump casing 10 is a one-piece structure, but for the sake of convenience, it will be described as having three parts: a flange portion 103, a first casing portion 104 and a second casing portion 105. As shown in FIG. A first intake port 101 and a second intake port 102 are arranged side by side in the flange portion 103 . As shown in FIG. 2, a region FP between the first intake port 101 and the second intake port 102 extends to a predetermined position inside the pump casing 10 to separate the first intake port 101 and the second intake port 102 from each other. A partition wall 103K is formed to separate the . The flange portion 103 is a region having a predetermined thickness in the axial direction where the first and second intake ports 101 and 102 are formed, and the partition wall 103K also has that thickness.

A seal groove 106 for the first intake port 101 and a seal groove 107 for the second intake port 102 are formed in the flange portion 103 . Holes 108 for bolting the flange portion 103 to the chamber to be evacuated are formed in the peripheral portion of the flange portion 103, as shown in the A view of FIG. 3(a).

A first housing space 104</b>S communicating with the first intake port 101 and the second intake port 102 is formed inside the first casing portion 104 . The first housing space 104S is a space extending below the first intake port 101 and the second intake port 102 inside the pump casing 10, and has a cross-sectional shape as shown in FIG. 3(b). The first accommodation space 104S is composed of a region 104S1 in contact with the first intake port 101 and a region 104S2 in contact with the second intake port 102. As shown in FIG. As shown in FIG. 3B, the partition 103K provided in the flange portion 103 does not exist between the region 104S1 and the region 104S2. In region 104S1, first pump stage PS1 and exhaust passage portion 34 are arranged coaxially with first intake port 101 (see FIG. 1).

As shown in FIG. 2, a second housing space 105S is provided below the first area 104S1 that forms the first housing space 104S. The second housing space 105S is a cylindrical space formed inside the second casing portion 105, as shown in the CC cross-sectional view of FIG. As shown in FIG. 1, all of the second pump stage PS2 and part of the third pump stage PS3 are disposed in the second accommodation space 105S.

(Improved exhaust speed at the second intake port)
Characteristic points of the turbo-molecular pump 1 of the present embodiment will be described. As described above, in the first housing space 104S, the first air intake port 104S2 is located at the flange portion 103 between the first region 104S1 facing the first air inlet 101 and the second region 104S2 facing the second air inlet 102. A partition wall 103K formed between the port 101 and the second intake port 102 is not formed. As described above, the gas in the second chamber connected to the second inlet 102 is evacuated by the second pump stage PS2 and the third pump stator PS3. At this time, the gas flows from the second intake port 102 into the exhaust passage section 34 through the second region 104S2 and the opening 3120 provided in the side wall of the spacer 312c. As described above, the partition 103K does not exist between the first area 104S1 and the second area 104S2. Therefore, the conductance from the second intake port 102 to the exhaust passage portion 34 is configured to be as large as possible. As a result, the exhaust speed at the second intake port 102 can be improved.

In the turbo-molecular pump described in Patent Document 1, a wall is provided between the first intake port and the second intake port, and FIG. 5 shows an example (comparative example) in which such a wall portion is provided. It is a figure which shows. FIG. 5(a) shows a part of the cross section of the flange portion 103 and the first casing portion 114 in the case of the comparative example. Only the laminate of 311 and spacers 313a, 313b and 313c is shown. FIG. 5(b) is a cross-sectional view taken along line DD, showing only the pump casing 10 and the spacer 313c.

First casing portion 114 in the comparative example of FIG. 5 is different in configuration from first casing portion 104 of the present embodiment. A wall portion 116 protrudes downward in the drawing from the flange portion 103, and its tip reaches the upper end of the opening 3130 of the spacer 313c. In other words, the plurality of stator blade stages 311 constituting the first pump stage PS1 are sandwiched between the plurality of spacers 313a, 313b, and 313, but the wall portion 116 extends from the flange portion 103 to the maximum inside the pump casing 10. It extends to the position of the lower spacer 313c.

In the comparative example of FIG. 5, the exhaust passage from the second intake port 102 to the opening 3130 is composed of a region 114S1 and a region 114S2 formed through the wall portion . A region 114 S 2 is a through hole formed in the wall portion 116 . The conductance from the second intake port 102 of the flange portion 103 to the exhaust passage portion 34 is the conductance C1 of the columnar region 114S1 having the diameter D1 and the height Lz, and the conductance of the region 114S2 connecting the region 114S1 and the opening 3130 of the spacer 313c. C2 and the conductance C3 of the aperture 3130 are combined to form a conductance.

On the other hand, in the present embodiment, as shown in the BB cross-sectional view of FIG. 3(b), the first casing portion 104 is not provided with the wall portion 116 unlike the comparative example. FIG. 6(a) is a diagram illustrating an exhaust passage from the second intake port 102 to the opening 3120 in this embodiment. Of the constituent elements of the first pump stage PS1, only the stator blade stage 311 and spacers 312a to 312c on the stator side are shown, as in the case of FIG. 5(a). FIG. 6(b) is an enlarged view of the laminated portion of the spacer 312b and the stator blade stage 311. As shown in FIG. In this embodiment, the spacer 312b is composed of a gripping portion 3122 that grips the stator blade stage 311 together with the adjacent spacer, and a fitting portion 3121 that fits the outer peripheral side of the gripping portion 3122 of the adjacent spacer 312b. I made it

The gripping portion 3122 has an annular shape that contacts the upper surface of the lower stator blade and the lower surface of the upper stator blade. The fitting portion 3121 has an annular shape extending downward in the rotation axis direction from the lower end of the outer peripheral side of the grip portion 3122 . It is configured to cover the radial outer peripheral surface of the grip portion 3122 of the spacer. The radial thickness of the fitting portion 3121 is formed to be thinner than the radial thickness of the grip portion 3122 . As shown in FIG. 6A, the outer peripheral surface of the fitting portion 3121 slightly protrudes from the inner peripheral surface (right side surface in the drawing) of the partition wall 103K toward the outer peripheral surface (left side surface in the drawing) of the partition wall 103K. That is, since the outer diameter of the fitting portion 3121 is set smaller than the outer diameter of the partition wall 103K, the presence of the fitting portion 3121 hardly lowers the conductance.

The exhaust passage from the second intake port 102 to the opening 3120 in FIG. 6A coincides with the region 104S2 (see FIG. 2) in contact with the second intake port 102. As shown in FIG. A circle Cr with a diameter D1 indicated by a dashed line in the BB cross section of FIG. 3 indicates the shape of the xy cross section of the region 114S1 shown in FIG. It is larger than the xy cross-sectional area of 114S1. Also, the dimension in the z direction is Lz, which is the same as the region 114S1 shown in FIG. Thus, conductance C4 of region 104S2 is greater than conductance C1 of region 114S1.

Furthermore, the partition wall 113K of the flange portion 103 does not protrude into the region 104S2, which is the exhaust passage. Therefore, the region 104S2 is in contact with the opening 3120 of the spacer 312c and also in contact with the outer peripheral surface of the first pump stage PS1 without passing through the communication path 114S2 bored in the wall portion 116 like the region 114S2 shown in FIG. ing. Therefore, the conductance from the second intake port 102 of the flange portion 103 to the exhaust passage portion 34 is a conductance obtained by combining the conductance C4 of the region 104S2 and the conductance C3 of the opening 3120 of the spacer 312c, and in the case of the comparative example shown in FIG. found to be larger than

That is, in the present embodiment, the wall portion 116 as shown in the comparative example (FIG. 5) is not provided in the first housing space 104S of the first casing portion 104. The conductance can be made larger, and the exhaust speed at the second intake port 102 can be improved.

(Prevention of Decrease in Exhaust Speed of First Air Inlet)
By the way, when the wall portion 116 is provided as shown in FIG. 5A, the outer peripheral surface of the laminate of the stator blade stage 311 and the spacers 313a, 313b, and 313c is not exposed to the region 114S1. On the other hand, when there is no wall portion (inner wall) in the first accommodation space 104S as shown in FIGS. is exposed to the region 104S2 on the second inlet 102 side.

Since region 104S2 communicates with exhaust passage 34 through opening 3120, the pressure in region 104S2 is at the same level as the pressure in exhaust passage 34, and the pressure in first pump stage PS1 (i.e., the pressure in the inner space of spacer 312b). pressure). Therefore, if there is a gap leading from the outer circumference to the inner circumference of the first pump stage PS1, a backflow of gas from the region 104S2 to the inside of the first pump stage PS1 occurs, and the exhaust speed at the first intake port 101 decreases. A problem arises.

FIG. 7 shows the transition from the region 104S2 to the first pump stage PS1 in the case where the structure of the spacers of the first pump stage PS1 is the same as the spacers 313b and 313c shown in FIG. 5(a) in this embodiment. is a diagram for explaining the influence of backflow of . Assume that the exhaust speed at the first inlet 101 is S, the pressure on the side of the first inlet 101 is P1, and the pressure on the downstream side of the first pump stage PS1 is Pn+1. In this case, the compression ratio Kt of the entire first pump stage PS1 is defined as "Kt=Pn+1/P1". Also, the exhaust flow rate Q of the first pump stage PS1 is Q=P1×S.

It is also assumed that n pairs of rotor blade stages 211 and stator blade stages 311 (hereinafter referred to as turbine blade stage pairs) are provided in the first pump stage PS1. As shown in FIG. 7, when the compression ratio of the m-th set of turbine blade stage pairs is represented by Km (where m=1, 2, . . . , n), the compression ratio of the entire first pump stage PS1 Kt ( =Pn+1/P1) is represented by the following equation (1). The compression ratio Km is defined as Km=Pm+1/Pm, where P1 to Pn are the pressures in the respective turbine blade stage pairs.
Kt = Kn x Kn-1 x ... x K2 x K1 (1)

In the case of the first casing portion 104 of the present embodiment without the wall portion 116 as shown in FIG. Backflow of gas from the outer peripheral side to the inner peripheral side (rotor side) through the gap between the rotors becomes a problem. In FIG. 7, q2 and qn represent flow rates of backflow in the second and n-th turbine blade stage pairs. Letting C(m) be the conductance of the gap between the laminated parts in each turbine blade stage pair (where m=1, 2, . It is represented by Formula (2). In this way, the backflow qm depends on the pressure difference = Pn+1 - Pm, but for the sake of simplicity, the backflow qm will be described using a larger estimated backflow qm as in equation (3).
qm=(Pn+1-Pm)×C(m) (2)
qm=Pn+1×C(m) (3)

The exhaust flow rate Qm (m=1, 2, . . . n) at each turbine blade stage pair is expressed as Qm=Pm×Sm using the exhaust velocity Sm at each turbine blade stage pair. However, since the exhaust flow rate Qm in each turbine blade stage pair is the same as the exhaust flow rate Q of the first pump stage PS1, Qm=Pm×Sm=Q. Further, the exhaust speed S1 of the first (uppermost) turbine blade stage pair is the same value as the exhaust speed S of the first pump stage PS1. Considering the balance between the exhaust flow rate Qm and the backflow qm in the m-th turbine blade stage pair, at least qm<Qm must be satisfied in order for the turbine blade stage pair to have the exhaust capacity. In other words, conductance C(m) must satisfy the following equation (4).
C(m)<(Pm/Pn+1)×Sm (4)

By the way, as described above, since the exhaust flow rate Qm (=Sm×Pm) in each turbine blade stage pair is equal to Q (=S×P1), the exhaust speed Sm is expressed as Sm=(P1/Pm)×S. be. If this is applied to the right side of equation (4), the right side can be transformed to = (P1/Pn+1) x S = (1/Kt) x S, and equation (4) can be rewritten as the following equation (5). can be done. That is, it is preferable that any spacer of the first pump stage PS1 has a structure in which the gap conductance C(m) satisfies the expression (5).
C(m)<(1/Kt)S...(5)

8A and 8B are diagrams for explaining the relationship between the stator blade stage 311 and the spacer 312b. FIG. 8A is a plan view of the stator blade stage 311, and FIG. 1 is a view seen from above, and (c) is a cross-sectional view taken along the line EE. Generally, one stator blade stage 311 is composed of two halved stator blades 311a and 311b as shown in FIG. 8(a). Each of the stator blades 311a and 311b has an inner ring portion 3110 and an outer ring portion 3111, and a plurality of turbine blades 3112 are provided between the inner ring portion 3110 and the outer ring portion 3111.

As shown in FIG. 8B, a pair of stator blades 311a and 311b forming a stator blade stage 311 are held by a pair of spacers 312b arranged vertically (up and down in the figure) in the axial direction. As shown in FIG. 8(c), the outer ring portion 3111 of the stator blade 311a gripped by the spacer 312b is attached to the lower surface of the gripped portion 3122 of the upper spacer 312b and the upper surface of the gripped portion 3122 of the lower spacer 312b. It's in close contact. However, the seam F between the stator blades 311a and 311b is difficult to bring the facing surfaces into close contact with each other, and tends to become the path of the above-described reverse flow.

In this embodiment, as shown in FIG. 6(b), the spacer 312b is fitted to the gripping portion 3122 that grips the stator blade stage 311 and the outer peripheral side of the gripping portion 3122 of the spacer 312b that is adjacent to the downstream side of the exhaust gas. It is configured with a fitting portion 3121 that fits. Since the outer peripheral surface of the outer ring portion 3111 is covered with the fitting portion 3121, the outer peripheral side of the seam F between the stator blades 311a and 311b shown in FIG. C(m) can be made small. That is, by suppressing the conductance C(m) to a small value that satisfies the equation (5), it is possible to prevent deterioration of exhaust characteristics at the first intake port 101 . Note that the spacers 312a and 312c also have grip portions and fitting portions similar to those of the spacer 312b.

Moreover, as described above, it is difficult to bring the facing surfaces into close contact with each other at the seam F between the stator blades 311a and 311b shown in FIG. Therefore, the stator blades are arranged so that the seam F is not located on the side of the region 104S2 in FIG. By arranging 311a and 311b, backflow of gas from the region 104S2 can be suppressed.

(Modification 1)
FIG. 9 is a view showing Modification 1 of the above-described embodiment, and is a cross-sectional view of spacer 312b. Generally, in a turbo-molecular pump, when a rotor blade stage that rotates at high speed is broken, the stator blade stage, the spacer, and the pump casing dispersively absorb the breaking energy, thereby suppressing the breakage of the pump casing. However, in the configuration shown in FIGS. 1 to 3, the first pump stage PS1 does not have a pump casing on the outer peripheral side in the region in contact with the region 104S2, so the pump casing cannot disperse and absorb the breaking energy in that region. . Therefore, in the region where the pump casing does not exist on the outer peripheral side, the ability to absorb the breaking energy is reduced, and the stator portion 31 is more likely to break than in the other regions.

In Modified Example 1, in order to compensate for the decrease in strength against breaking energy due to the omission of the wall portion, a material superior in tensile strength to the conventional aluminum-based material is used as the material of the spacers 312a and 312b. Specifically, stainless steel and carbon fiber reinforced plastic (CFRP) are used. The spacer 312b shown in FIG. 9 uses carbon fiber reinforced plastic (CFRP). The spacer 312a is also made of CFRP.

CFRP is a composite material in which a bundle of carbon fibers is impregnated with plastic (such as epoxy resin), and has a high tensile strength in the direction of the carbon fibers. In the spacer 312b, the carbon fiber 3123 extends in the circumferential direction and is wound in a ring shape. In this way, by making the extending direction of the CFRP carbon fibers 3123 the circumferential direction, the tensile strength of the spacers 312a and 312b in the circumferential direction is increased.

CFRP is strong against tension in the direction of carbon fibers, and its tensile strength reaches several thousand MPa. This is much larger than aluminum-based materials generally used as spacer materials, and even larger than stainless steel. For example, SUS304 has a tensile strength of about 520 MPa. In this way, by using a material having a higher tensile strength than the conventional aluminum-based material for the spacers 312a and 312b, it is possible to increase the amount of breaking energy absorbed when the spacers 312a and 312b are deformed or broken. It is possible to prevent a decrease in safety due to the omission of the wall portion.

(Modification 2)
FIG. 10 is a diagram showing Modification 2 of the above-described embodiment. In the embodiment described above, as shown in FIG. 6B, the fitting portion 3121 provided on the spacer 312b is fitted to the outer peripheral side of the gripping portion 3122 of the adjacent spacer 312b, whereby the first portion from the region 104S2 is moved. A reverse flow into the 1-pump stage PS1 is prevented. On the other hand, in Modified Example 2, a cylindrical shielding member 315 is arranged on the outer peripheral side of the stack of the stator blade stage 311 of the first pump stage PS1 and the spacer, so that the outer peripheral surface of the stack is exposed to the atmosphere of the region 104S2. The structure is such that it is not exposed, and the backflow described in FIG. 7 is prevented.

Spacers 314a and 314b are ring-shaped like spacer 313a shown in FIG. and the same as the outer diameter. The spacer 314c is a spacer having the same shape as the spacer 312c shown in FIG. 6, and has an opening 3120 having the same shape. The inner and outer diameters of the shielding member 315 are set to be the same as the inner and outer diameters of the fitting portion 3121 of the spacer 312b shown in FIG. 6(b). As in the case of the fitting portion 3121 shown in FIG. 6, the outer diameter of the shielding member 315 is set smaller than the outer diameter of the partition wall 103K. is set to be much thinner, and the presence of the shielding member 315 hardly lowers the conductance.

The shielding member 315 and the spacers 314a to 314c may be made of an aluminum-based material similar to that of conventional spacers, or may be made of CFRP or stainless steel described in the first modification. By using CFRP or stainless steel, it is possible to improve the strength against breaking energy as in the first modification. Further, the spacers 314a to 314c may be provided with a fitting structure like the spacers 312a to 312c shown in FIG. 6 to prevent backflow, and the shielding member 315 on the outer peripheral side may be a member dedicated to improving strength.

(GC mass spectrometer)
FIG. 11 is a diagram showing an example of a mass spectrometer using the turbomolecular pump 1 of the present embodiment, and is a schematic diagram showing the basic configuration of a gas chromatograph mass spectrometer (GC mass spectrometer) 70. A gas chromatograph-mass spectrometer 70 includes a gas chromatograph section 71 , an ion sending section 72 , a mass analysis section 73 , and a turbomolecular pump 1 .

The gas chromatograph section 71 is provided with a column oven 711 , a column (capillary column) 712 and an injector 713 . Although not shown, the injector 713 has a sample vaporization chamber for heating and vaporizing the liquid sample, and the sample vaporization chamber is supplied with a carrier gas (He gas) at a predetermined flow rate. A liquid sample injected into the sample vaporization chamber by a microsyringe or the like is vaporized in the sample vaporization chamber and sent into the column 712 along with the carrier gas flow. Column 712 is heated to moderate temperature by column oven 711 .

The vaporized sample (ie sample gas) moves through the column 712 with the carrier gas. Although the sample gas contains a plurality of components, the speed at which each component travels through the column 712 is different. As a result, each component is temporally separated, reaches the outlet of the column 712 , and is guided from the sample introduction tube 714 to the ion delivery section 72 .

The ion sending section 72 ionizes the sample gas and sends it to the mass spectrometry section 73 , and includes an ionization chamber 721 and an ion transport optical system 722 . Molecules of the gas component guided from the sample introduction pipe 714 to the ion delivery section 72 are introduced into the ionization chamber 721 . Molecules of the gas component introduced into the ionization chamber 721 are ionized by thermal electrons emitted from a filament 725 provided in the ionization chamber 721 . The generated ions are ejected from the ionization chamber 721 by the ejection electrode 726 to which a positive voltage is applied.

Ions emitted from the ionization chamber 721 are converged by an ion transport optical system 722 having a linear optical axis and guided to a mass spectrometer 73 . The mass spectrometer 73 has a quadrupole mass spectrometer 731 , an ion lens 732 and a detector 733 . Ions converged by the ion transport optical system 722 are guided to a quadrupole mass spectrometer 731 . A voltage obtained by superimposing a DC voltage and a radio frequency voltage (RF voltage) is applied to the quadrupole mass spectrometer 731, and only ions having a mass corresponding to the applied voltage pass through the quadrupole mass spectrometer 731. do. Ions passing through a quadrupole mass spectrometer 731 are converged by an ion lens 732 and detected by a detector 733 .

A differentially pumped chamber 741 in which a quadrupole mass spectrometer 731, an ion lens 732 and a detector 733 are provided, and a differentially pumped chamber 742 in which an ionization chamber 721 and an ion transport optical system 722 are provided, It is partitioned by a wall portion 740 in which holes 740a for passing ions are formed. A first intake port 101 on the high-vacuum side of the turbo-molecular pump 1 is connected to a differential exhaust chamber 741 , and a second intake port is connected to a differential exhaust chamber 742 .

In order to improve the detection accuracy of the quadrupole mass spectrometer 731 and the detector 733, the differential evacuation chamber 741 is preferably highly vacuumed. Therefore, a wall portion 740 having a hole 740a is provided between the differential pumping chamber 741 and the differential pumping chamber 742, and the differential pumping chamber 741 and the differential pumping chamber 742 are separated from each other by the first intake air of the turbo-molecular pump 1. A differential exhaust system is employed in which air is exhausted individually by the port 101 and the second intake port 102 . By providing the wall portion 740, the inflow of gas from the differential evacuation chamber 742 to the differential evacuation chamber 741 is suppressed, and the differential evacuation chamber 741 can be made into a higher vacuum.

In this case, the lower the pressure in the differential evacuation chamber 742, the less gas flows from the differential evacuation chamber 742 to the differential evacuation chamber 741, and the higher the vacuum in the differential evacuation chamber 741 can be. Therefore, it is desirable for the turbo-molecular pump 1 to increase the exhaust speed of the second intake port 102 while maintaining the exhaust performance of the first intake port 101 . In the turbo-molecular pump 1 of the present embodiment, as described above, by not providing a conventional wall in the pump casing 10, the exhaust speed of the second intake port 102 is improved. Suitable as a vacuum pump for mass spectrometers.

Further, when the gas that has flowed into the second inlet 102 flows back into the first pump stage PS1, the exhaust performance on the first inlet 101 side deteriorates, adversely affecting the performance of the quadrupole mass spectrometer 731 and the detector 733. effect. In the present embodiment, the spacers 312b and 312b are configured as shown in FIGS. 6 and 8 to prevent the above backflow. It is possible to improve accuracy.

(ICP mass spectrometer)
FIG. 12 is a diagram showing another example of a mass spectrometer using the turbomolecular pump 1 of the present embodiment, and is a schematic diagram showing the basic configuration of an inductively coupled plasma mass spectrometer (ICP mass spectrometer) 80. is. The turbo-molecular pump 1 of the present embodiment can be used not only for the GC mass spectrometer 70 described above, but also for the evacuation system of the ICP mass spectrometer 80 .

The ICP mass spectrometer 80 is a device that passes ions generated by a plasma torch 81 through an interface section 82 and an ion converging section 83 to guide specific ions to a mass spectrometry section 84 for detection. The interface section 82 includes a sampling cone 821 and a skimmer cone 822 arranged back and forth along the direction of the ion passage axis. A differential evacuation chamber 823 between the sampling cone 821 and the skimmer cone 822 is evacuated by a roughing pump (not shown).

An orifice 821a is formed at the tip of the sampling cone 821, and part of the plasma P generated by the plasma torch 81 enters the differential exhaust chamber 823 through the orifice 821a. A part of the plasma that has entered the differential pumping chamber 823 passes through an orifice 822a formed at the tip of the skimmer cone 822, and is guided to a subsequent stage in the form of an ion beam. The ion beam that has passed through the orifice 822 a is converged by the ion lens 831 of the ion converging section 83 and passes through the hole 850 a of the wall section 850 provided between the differential pumping chamber 832 and the differential pumping chamber 843 to the mass spectrometer 84 . It is led to a quadrupole mass spectrometer 841 . A quadrupole mass spectrometer 841 mass separates specific ions from the ion beam, and the separated ions are detected by an ion detector 842 .

As described above, the differential evacuation chamber 823 of the interface section 82 is evacuated by the roughing pump, while the differential evacuation chamber 832 of the ion converging section 83 is evacuated by the second intake port 102 of the turbomolecular pump 1 . , the differential evacuation chamber 843 of the mass analysis unit 84 is evacuated by the first intake port 101 of the turbomolecular pump 1 . In the case of the ICP mass spectrometer 80 as well, in order to improve the detection accuracy of the mass spectrometer 84, it is preferable to lower the pressure in the differential pumping chamber 832 adjacent to the differential pumping chamber 843. FIG.

The effects of the turbo-molecular pump 1 of the embodiment and the example described above are summarized as follows.
(1) As shown in FIG. 6(a), the turbo-molecular pump 1 does not have the wall portion 116 like the comparative example in FIG. A second region 104S2 forming an exhaust passage from 102 to opening 3120 is in contact with the outer peripheral surface of first pump stage PS1, second intake port 102, and opening 3120 of exhaust passage portion . Therefore, the cross-sectional area of the region 104S2 functioning as an exhaust passage from the second intake port 102 to the opening 3120 of the exhaust passage portion 34 can be increased, and the conductance from the second intake port 102 to the exhaust passage portion 34 is improved. . As a result, the exhaust speed at the second intake port 102 can be improved.

(2) The first pump stage PS1 includes a first pump rotor portion 21 composed of a plurality of rotor blade stages 211 and a first stator portion 31 composed of alternately laminated stator blade stages 311 and a plurality of spacers. , and a shielding member arranged to cover the outer peripheral side of the stator blade stage 311 held by the spacer. For example, in the example shown in FIG. 6B, the spacer is the gripping portion 3122 and the shielding member is the fitting portion 3121 . In the example shown in FIG. 10, the spacers are spacers 314a, 314b, and 314c, and a cylindrical shielding member 315 is arranged on the outer peripheral side thereof.

By providing the fitting portion 3121 and the shielding member 315, it is possible to suppress the backflow of gas from the region 104S2 into the first pump stage PS1, thereby preventing the decrease in exhaust speed at the first intake port 101 caused by the backflow. can do. In that case, C<(1/Kt)S is set for each stator blade stage 311 of the first pump stage PS1. However, C is the conductance related to the backflow of gas from the outer peripheral side of the shielding member of the stator blade stage 311 held by the spacer into the first pump stage PS1, S is the exhaust speed at the first intake port 101, and Kt is the first pump stage PS1. It is the compression ratio of one pump stage PS1.

(3) In addition, shielding member 315 and spacers 314a to 314c in FIG. 10, and spacer 312b integrally formed with fitting portion 3121 as a shielding member as shown in FIG. By using a material (e.g., CFRP) larger than the spacer 312b, it is possible to increase the amount of absorption of the fracture energy by the spacer 312b when the rotor is fractured, thereby suppressing fracture of the pump casing 10 and improving safety. can be done.

(4) In the GC mass spectrometer 70 and the ICP mass spectrometer 80, the first differential evacuation chamber (the differential evacuation chamber 741 in FIG. 11 and the differential evacuation chamber 843 in FIG. 12) in which the mass analysis unit is accommodated, A second differentially pumped chamber (differentially pumped chamber 742 in FIG. 11 and differentially pumped chamber 832 in FIG. 12) that accommodates an ion sending unit that sends an ionized sample to the mass spectrometry unit is provided. The first intake port 101 of the turbo-molecular pump 1 is connected to the first differential exhaust chamber for exhaust, and the second differential exhaust chamber is connected to the second intake port 102 for exhaust. The first differential pumping chamber is kept at a higher vacuum than the second differential pumping chamber. can be made lower. As a result, the inflow of gas and ions from the second differential pumping chamber is suppressed, the first differential pumping chamber can be brought to a higher vacuum, and the analysis accuracy of the mass spectrometer can be improved.

Although various embodiments and modifications have been described above, the present invention is not limited to these contents. For example, the present invention can also be applied to a turbo-molecular pump having three pump stages with turbine blade stages and having a third intake port flowing into the third pump stage, that is, having three intake ports. be able to. Other aspects conceivable within the scope of the technical idea of the present invention are also included in the scope of the present invention.

REFERENCE SIGNS LIST 1 turbomolecular pump 10 pump casing 21 first pump rotor section 31 first stator section 34 exhaust passage section 70 gas chromatograph mass spectrometer 72 ion sending section 73, 84 Mass spectrometry unit 80 Inductively coupled plasma mass spectrometer 101 First intake port 102 Second intake port 103 Flange portion 103K Partition wall 104 First casing portion 104S First housing space 104S1, 104S2, 114S1, 114S2... area, 105... second casing part, 105S... second accommodation space, 211... rotor blade stage, 311... stator blade stage, 312a to 312d, 313a to 313c, 314a to 314c... spacer, 315... Shielding member 741, 742, 823, 832, 843... Differential pumping chamber 3121... Fitting part 3122... Gripping part PS1... First pump stage PS2... Second pump stage

Claims (9)

a pump casing having a flange portion, a first casing portion and a second casing portion;
a first intake port and a second intake port arranged side by side on the flange;
a first accommodation space provided in the first casing portion, the first accommodation space including a first region corresponding to the first air inlet and a second region corresponding to the second air inlet;
a second housing space provided in the second casing;
a first pump stage provided facing the first inlet in the first area of the first housing space;
a second pump stage provided in the second housing space coaxially with the first pump stage and spaced from the first pump stage by a predetermined distance;
The gas is formed between the first pump stage and the second pump stage in the first housing space and is exhausted by the first pump stage from the first intake port and the gas passing through the second region. an exhaust confluence portion where the gas from the second intake port merges,
The first pump stage comprises:
a pump rotor section comprising a plurality of rotor blade stages;
A pump stator section formed by alternately stacking a plurality of stator blade stages and a plurality of spacers,
A partition wall separating the first intake port and the second intake port is formed in the flange portion,
The partition wall is not formed in the first casing portion, and the region of the outer periphery of all the rotor blade stages and all the stator blade stages of the first pump stage and facing the second region is A turbomolecular pump exposed in the second region. In the turbomolecular pump according to claim 1,
The first pump stage comprises:
a pump rotor section comprising a plurality of rotor blade stages;
A pump stator section formed by alternately stacking a plurality of stator blade stages and a plurality of spacers,
The spacer includes a grip portion that grips the stator blade stage together with the adjacent spacer so as to sandwich the stator blade stage, and a fitting portion that extends from the radial outer periphery of the grip portion and covers the radial outer periphery of the stator blade stage. have
The turbo-molecular pump, wherein the radial outer peripheral surface of the spacer is exposed to the second region. In the turbomolecular pump according to claim 1 ,
The first pump stage comprises:
a pump rotor section comprising a plurality of rotor blade stages;
A pump stator section formed by alternately stacking a plurality of stator blade stages and a plurality of spacers,
The spacer includes a grip portion that grips the stator blade stage together with the adjacent spacer so as to sandwich the stator blade stage, and a fitting portion that extends from the radial outer periphery of the grip portion and covers the radial outer periphery of the stator blade stage. have
a radial outer peripheral surface of the spacer is exposed to the second region;
A radial thickness of the fitting portion is formed to be thinner than a radial thickness of the gripping portion, and an outer diameter of the fitting portion is set smaller than an outer diameter of the partition wall. molecular pump. a pump casing having a flange portion, a first casing portion and a second casing portion;
a first intake port and a second intake port arranged side by side on the flange;
a first accommodation space provided in the first casing portion, the first accommodation space including a first region corresponding to the first air inlet and a second region corresponding to the second air inlet;
a second housing space provided in the second casing;
a first pump stage provided facing the first inlet in the first region of the first housing space;
a second pump stage provided in the second housing space coaxially with the first pump stage and spaced from the first pump stage by a predetermined distance;
The gas is formed between the first pump stage and the second pump stage in the first housing space and is exhausted by the first pump stage from the first intake port and the gas passing through the second region. an exhaust confluence portion where the gas from the second intake port merges,
A partition wall separating the first intake port and the second intake port is formed in the flange portion,
The partition wall is not formed in the first casing part, and a region of the first pump stage facing the second region is exposed to the second region,
The first pump stage comprises:
a pump rotor section comprising a plurality of rotor blade stages;
A pump stator section formed by alternately stacking a plurality of stator blade stages and a plurality of spacers,
The spacer includes a grip portion that grips the stator blade stage together with the adjacent spacer so as to sandwich the stator blade stage, and a fitting portion that extends from the radial outer periphery of the grip portion and covers the radial outer periphery of the stator blade stage. have
a radial outer peripheral surface of the spacer is exposed to the second region ;
The stator blade stage is configured by joining two half-split stator blades,
An outer peripheral surface other than the connecting portion of the two halves of the stator blades faces the second region, and the connecting portion of the two halves of the stator blades does not face the second region. pump. In the turbomolecular pump according to claim 1,
The first pump stage comprises:
a pump rotor section comprising a plurality of rotor blade stages;
a pump stator section formed by alternately stacking a plurality of stator blade stages and a plurality of spacers;
a shielding member disposed on the radially outer peripheral side of the spacer and covering the radially outer peripheral side of the stator blade stage and the radially outer peripheral side of the spacer;
The turbo-molecular pump, wherein the outer diameter of the shielding member is set smaller than the outer diameter of the partition wall. In the turbomolecular pump according to any one of claims 2 to 4,
C is the conductance related to the reverse flow of gas from the outer peripheral side of the stator blade stage gripped by the spacer into the first pump stage, S is the exhaust speed at the first intake port, and Kt is the compression ratio of the first pump stage. , wherein C<(1/Kt)S is satisfied at each stator blade stage of said first pump stage. In the turbomolecular pump according to any one of claims 2 to 4,
The turbo-molecular pump, wherein the spacer is made of a material having a higher tensile strength than an aluminum-based material. In the turbomolecular pump according to claim 5,
The turbo-molecular pump, wherein the shielding member is made of a material having a higher tensile strength than an aluminum-based material. a first differential evacuation chamber in which the mass spectrometer is accommodated;
a second differentially pumped chamber containing an ion delivery unit that delivers the ionized sample to the mass analysis unit;
a turbomolecular pump according to any one of claims 1 to 8,
A mass spectrometer, wherein the first intake port of the turbo-molecular pump is connected to the first differential pumping chamber, and the second intake port is connected to the second differential pumping chamber.

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