Information
-
Patent Grant
-
6419444
-
Patent Number
6,419,444
-
Date Filed
Tuesday, May 16, 200024 years ago
-
Date Issued
Tuesday, July 16, 200221 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Look; Edward K.
- Nguyen; Ninh
Agents
-
CPC
-
US Classifications
Field of Search
US
- 415 72
- 415 73
- 415 75
- 415 90
- 416 176
- 416 177
-
International Classifications
-
Abstract
A screw groove-type pump has a rotor member mounted for undergoing rotation, a stator member arranged so as to be coaxial with the rotor member and having a peripheral wall disposed opposite to and spaced-apart from a circumferential wall of the rotor member, an inlet port for introducing gas into a space between the circumferential wall of the rotor member and the peripheral wall of the stator member, and an outlet port for discharging gas introduced into the space between the circumferential wall of the rotor member and the peripheral wall of the stator member. A screw groove is formed on one of the circumferential wall of the rotor member and the peripheral wall of the stator member for transferring gas introduced into the inlet port through the space between the circumferential wall of the rotor member and the peripheral wall of the stator member and to the outlet port during rotation of the rotor member. The depth of the screw groove at a point thereof which is nearest the inlet port is equal to or larger than ¼ the diameter of one of the circumferential wall of the rotor member and the peripheral wall of the stator member. An angle of elevation of the screw groove with respect to a radial axis of the rotor member decreases toward the outlet port from the inlet port.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a screw groove type vacuum pump, and a complex pump and a vacuum pump system both of which include the screw groove type vacuum pump. More specifically, the present invention relates to a screw groove type vacuum pump, a complex pump and a vacuum pump system with which excellent exhaust speed can be attained.
2. Description of the Related Art
Screw groove type vacuum pumps have conventionally been well known. Any of these screw groove type vacuum pumps is provided with a rotor member that rotates and a stator member fixedly arranged so as to be coaxial with the rotor member, and has a screw groove formed on one of a circumferential wall of the rotor member and an opposite wall of the stator member which is opposite to the circumferential wall. The rotor member is rotated to introduce gas from an inlet port into the screw groove and to then transfer the gas along the screw groove, thereby discharging the gas through an outlet port.
In the screw groove type vacuum pump as such, conventionally, a screw sealing technique or the like is applied and the screw groove is designed so as to be rather shallow in order to efficiently transfer with the rotation of the rotor member gas molecules whose pressure is of a viscous flow region while utilizing the viscosity, and to thereby prevent the backward-flow from the outlet port side to the inlet port side.
However, conventional screw groove type vacuum pumps as described above have a problem of slow exhaust speed, for the average free path of gas molecules is large for gas in a molecule flow region and hence it is difficult to introduce the gas into the screw groove.
There has been proposed as a technique for improving the gas exhaust speed a screw groove type vacuum pump in which the screw groove at the inlet port is set deep and the depth of the screw groove is sharply reduced from thereon. In this screw groove type vacuum pump, the intake area of gas that is taken from the inlet port into the screw groove is large making it easy to introduce the gas in the molecule flow region into the screw groove.
On the side downstream of the inlet port, however, the pressure of the gas to be transferred through the screw groove is of an intermediate flow region between the molecule flow region and the viscous flow region, and the average free path of gas molecules is relatively large. For that reason, the gas molecules taken in are reflected by the bottom of the screw groove, or the like, which means that a sufficient exhaust speed cannot be obtained by merely setting the screw groove deeper at the inlet port.
The present inventors have found that, in a screw groove type vacuum pump, the pressure of the gas to be transferred through the screwed groove maintains the pressure of the intermediate flow region between the molecule flow region and the viscous flow region downstream of the inlet port until the gas reaches a certain depth of the pump in the axial direction, and that setting the flow path wider at this certain depth and securing the sealing from thereon result in prevention of reflection and backward flow of gas molecules, prevention of degradation of sealing, improved gas exhaust efficiency and excellent exhaust speed.
SUMMARY OF THE INVENTION
The present invention has been made on the basis of the findings as above, and an object of the present invention is therefore to provide a screw groove type vacuum pump, a complex vacuum pump and a vacuum pump system with which excellent exhaust speed can be attained.
In order to achieve the above object, the present invention provides a screw groove type vacuum pump comprising: a rotor member that rotates; a stator member fixedly arranged so as to be coaxial with the rotor member and having an opposite wall that is opposite to a circumferential wall of the rotor member; an inlet port for introducing gas into a space between the circumferential wall of the rotor member and the opposite wall of the stator member; and an outlet port for discharging the gas from the space between the circumferential wall of the rotor member and the opposite wall of the stator member, in which: a screw groove for transferring the gas from the inlet port with the rotation of the rotor member is formed on one of the circumferential wall of the rotor member and the opposite wall of the stator member; the depth of the screw groove at the nearest point to the inlet port is 20 mm or more, or is equal to or larger than ¼ the diameter, including the screw groove, of one of the circumferential wall of the rotor member and the opposite wall of the stator member, the depth of the screw groove is decreased toward the outlet port side from the inlet port side, and the depth of the screw groove in a region defined by the inlet port and a point on the rotor member which is 40 mm in the axial direction is 80% or more of the depth at the nearest point to the inlet port; and the slant of the screw groove with respect to the radial direction of the rotor member is decreased toward the outlet port side from the inlet port side, and maintains to be 80% or more of the slant at the inlet port until the thread reaches a point on the rotor member which is at least 40 mm in the axial direction.
According to the above screw groove type vacuum pump of the present invention, the depth of the screw groove may be decreased toward the outlet port side, which is downstream of a region defined by the inlet port and the point on the rotor member which is 40 mm in the axial direction, in proportion to the distance in the axial direction. This makes it possible to transfer gas in a viscous flow region with tight sealing.
The slant of the screw groove may be decreased toward the outlet port side, which is downstream of a region defined by the inlet port and the point on the rotor member which is 40 mm in the axial direction, in proportion to the distance in the axial direction. This makes it possible to transfer gas in the viscous flow region with tight sealing.
The slant of the screw groove may be decreased toward the outlet port side, which is downstream of a region defined by the inlet port and the point on the rotor member which is 40 mm in the axial direction, in logarithmic proportion to the distance in the axial direction. This makes it possible to transfer gas in the viscous flow region with tight sealing.
In order to achieve the above object, the present invention also provides a complex vacuum pump including the above screw groove type vacuum pump of the present invention.
In order to achieve the above object, the present invention also provides a vacuum pump system comprising the above screw groove type vacuum pump of the present invention and an auxiliary pump for taking in gas discharged through the outlet port of the screw groove type vacuum pump.
In order to achieve the above object, the present invention also provides a vacuum pump system comprising the above screw groove type vacuum pump of the present invention and an auxiliary pump for taking in gas discharged through the outlet port of the screw groove type vacuum pump that is included in the complex vacuum pump.
BRIEF DESCRIPTION OF THE DRAWINGS
In the accompanying drawings:
FIG. 1
is a sectional view showing the entire structure of a screw groove type vacuum pump according to an embodiment of the present invention;
FIG. 2
is a side view showing a rotor body of the screw groove type vacuum pump in
FIG. 1
;
FIG. 3
is an internal side view showing a state where a rotor body
61
of the screw groove type vacuum pump in
FIG. 1
is attached to a rotor shaft; and
FIG. 4
is a graph showing the relationship between the pressure and the exhaust speed in the screw groove type vacuum pump in
FIG. 1
, in comparison with a conventional screw groove type vacuum pump.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Hereinafter, a description will be given in detail of preferred embodiments of the present invention with reference to
FIGS. 1
to
4
.
FIG. 1
is a sectional view showing the entire structure of a screw groove type vacuum pump according to an embodiment of the present invention.
The screw groove type vacuum pump according to this embodiment is comprised of, as shown in
FIG. 1
, a rotor shaft
18
shaped like a column, a rotor
60
as a rotor member that is fixedly arranged on the rotor shaft
18
and rotates together with the rotor shaft
18
, and a casing or an exterior member
10
and a stator
70
which serve as a stator member.
The exterior member
10
has a cylindrical shape whose diameter does not vary over the entire length in the axial direction, and the rotor shaft
18
is coaxially arranged in the center of the exterior member
10
.
The exterior member
10
has at its upper end a flange
11
elongated outward in the radial direction. The flange
11
has bolt holes
11
a
drilled therein in a direction parallel to the axis. This flange
11
is fastened to, for example, an apparatus for manufacturing semiconductors with bolts or the like to connect an inlet port
16
formed inside the flange
11
to an outlet port of a vessel, e.g., a chamber, so that the interior of the vessel is communicated with the interior of the exterior member
10
.
The rotor shaft
18
is supported by a magnetic bearing
20
with a magnetic force, and is rotated with a driving force transmitted from a motor
30
. The stator
70
is provided with a tubular portion
71
that surrounds the rotor shaft
18
and is shaped like a tube and a base portion
72
to which the tubular portion
71
is fixed at an upper part.
The magnetic bearing
20
is a 5-axes-control type magnetic bearing, and is provided with: radial electromagnets
21
,
24
for generating a magnetic force in the radial direction of the rotor shaft
18
in the vicinity of the upper and lower ends of the rotor shaft
18
; radial sensors
22
,
26
for detecting the position of the rotor shaft
18
in the radial direction; axial electromagnets
32
,
34
for generating a magnetic force in the axial direction of the rotor shaft
18
; a metal disc
31
upon which the magnetic force in the axial direction, generated by the axial electromagnets
32
,
34
, acts; and an axial sensor
36
for detecting the position of the rotor shaft
18
in the axial direction.
The radial electromagnets
21
,
24
each include two pairs of electromagnets arranged on the tubular portion
71
of the stator
70
such that one pair is perpendicular to the other pair. The electromagnets in each pair are arranged so as to face one another with the rotor shaft
18
interposed therebetween. An excitation current is supplied to these radial electromagnets
21
,
24
to float the rotor shaft
18
with a magnetic force.
Outside the radial electromagnets
21
,
24
in the thrust direction, two paris of the radial sensors
22
and two pairs of the radial sensors
26
are arranged on the tubular portion
71
of the stator
70
such that the two pairs of the radial sensors
22
and the two pairs of radial sensors
26
are arranged with one pair being perpendicular to the other pair, corresponding to the radial electromagnets
21
,
24
. Two sensors in each sensor pair face one another with the rotor shaft
18
interposed therebetween. The control of the excitation current supplied to the radial electromagnets
21
,
24
is made, when the shaft is floated with a magnetic force, in response to position detection signals sent from the radial sensors
22
,
26
, to thereby keep the rotor shaft
18
at a predetermined position in the radial direction.
The metal disc
31
made of a magnetic member and shaped like a disc is fixed to a lower of the rotor shaft
18
. A pair of the axial electromagnets
32
and a pair of the axial electromagnets
34
are arranged on the base portion
72
of the stator
70
such that the electromagnets
32
face the, electromagnets
34
with the metal disc
31
interposed therebetween. The axial sensor
36
is arranged on the base portion
72
of the stator
70
while being opposed to the lower end of the rotor shaft
18
.
An excitation current flowing through the axial electromagnets
32
,
34
is controlled in response to a position detection signal sent from the axial sensor
36
, to thereby keep the rotor shaft
18
at a predetermined position in the axial direction.
It is possible for the vacuum pump to be driven in a clean environment, for the employment of the magnetic bearing
20
eliminates any mechanical contacts to produce no dust, and dispenses the pump of oils such as a sealing oil to generate no gas. The screw groove type vacuum pump according to this embodiment is thus suitable for an application in which a high cleanness is required as in manufacture of semiconductors.
The screw groove type vacuum pump according to this embodiment also has touch down bearings
38
,
39
arranged on an upper part and on a lower part of the rotor shaft
18
, respectively.
Usually, the rotor unit comprising the rotor shaft
18
and the parts attached to the shaft is, while being rotated by the motor
30
, axially supported by the magnetic bearing
20
without coming into contact with the bearing. The touch down bearings
38
,
39
are bearings for protecting the entire pump by axially supporting the rotor unit instead of the magnetic bearing
20
when the touch down takes place.
Accordingly, the touch down bearings
38
,
39
are arranged so that their inner rings do not come into contact with the rotor shaft
18
.
The motor
30
is arranged almost in the middle between the radial sensors
22
and
26
, inside the exterior member
10
, in the axial direction of the rotor shaft
18
. The motor
30
is energized to rotate the rotor shaft
18
as well as the rotor
60
that is attached to the shaft.
The rotor
60
is comprised of a rotor body
61
having a sectional shape like an inverted letter U and arranged on the outer periphery of the rotor shaft
18
, and a screw thread
63
elongated outward from the outer peripheral surface of the rotor body
61
. This rotor body
61
is attached to the top of the rotor shaft
18
with bolts
19
.
FIG. 2
is a side view of the rotor body
61
, and
FIG. 3
is an internal side view showing a state in which the rotor body
61
is attached to the rotor shaft
18
.
As shown in
FIG. 2
, the screw thread
63
of the rotor
60
is helically formed of plural threads so as to be coaxial with the axis of the rotor body
61
on the outer peripheral surface of the rotor body
61
. The space between the threads of the screw thread
63
is a screw groove
62
. As shown in
FIG. 3
, the rotor
60
is fixed to the rotor shaft
18
, and the edge face of the screw thread
63
faces the inner circumferential wall of the exterior member
10
with a gap that may be deemed as invariable over the entire length of the rotor body.
The screw groove
62
is communicated with the inlet port
16
so that gas from the chamber is introduced into the screw groove
62
. The screw groove
62
has at the nearest point to the inlet port
16
a depth D (distance from the free edge face of the screw thread
63
down to the outer peripheral surface of the rotor body
61
) of 20 mm or more. The slant θ with respect to the radial direction of the rotor
60
(an angle of elevation) of the screw groove
62
is 20 to 40° at the nearest point to the inlet port
16
.
The diameter of the rotor body
61
is increased downstream (toward the outlet port
17
side), as the distance from the inlet port
16
is increased, protruding to the inner circumferential wall of the exterior member
10
. The screw groove
62
is adapted to this increase in diameter of the rotor body
61
and the depth D of the groove is made shallow. The slope of the screw thread
63
with respect to the radial direction becomes gentle as it distances itself from the inlet port
16
and approaches the outlet port
17
, and the angle of elevation θ of the screw groove
62
accordingly takes a smaller value.
From the inlet port
16
to a point on the rotor body
61
which is 40 mm in the axial direction (in a range indicated by reference symbol B in the drawing), the depth D and the angle of elevation θ of the screw groove
62
are gently and continuously decreased but maintain to be 80% or more of the depth D and the angle of elevation θ at the inlet port
16
. The ratio of a distance d from the bottom of the screw groove
62
to the outer circumferential wall of the exterior member
10
to a distance c from the edge of the screw thread
63
to the inner circumferential wall of the exterior member
10
(clearance ratio: d/c in
FIG. 1
) is set to 50 or more.
On the side downstream of the region defined by the inlet port
16
and the point on the rotor body
61
which is 40 mm in the axial direction (region indicated by B in the drawing), the depth D and the angle of elevation θ of the screw groove
62
are continuously and gradually reduced as the distance from the outlet port
17
is decreased. The degree of this reduction is in proportion to the distance in the axial direction.
Given the distance in the axial direction between predetermined positions P and Q of the screw groove as Lv, and the depth of the screw groove
62
at the respective positions as Dp, Dq, the following expression is satisfied when the degree of reduction in the depth D of the screw groove
62
is in proportion to the distance in the axial direction:
Dp−Dq=k·Lv
[Numerical Expression 1]
where k is a constant that is a plus if P is closer to the inlet port than Q is and which is a minus if P is closer to the outlet port than Q is).
Therefore when, for example, the depth of the screw groove at the nearest point to the outlet port side in the region B is T mm and the depth D of the screw groove
62
at a point 1 cm in the axial direction down there is reduced therefrom by t mm, i.e., (T−t) mm, the depth D of the screw groove at a point 3 cm in the axial direction down the nearest point to the outlet port side in the region B is reduced by 3t mm, i.e., (T−3t) mm.
Given the distance in the axial direction between predetermined positions P and Q of the screw groove as Lv, and the angle of elevation of the screw groove
62
at the respective positions as θp, θq, the following expression is satisfied when the degree of reduction in the angle of elevation θ of the screw groove
62
is in proportion to the distance in the axial direction:
θp−θq=k·Lv
[Numerical Expression 2]
where k is a constant that is a plus if P is closer to the inlet port than Q is and which is a minus if P is closer to the outlet port than Q is).
Therefore when, for example, the angle of elevation of the screw groove at the nearest point to the outlet port side in the region B is S° and the angle of elevation of the screw groove
62
at a point 1 cm in the axial direction down there is reduced therefrom by s°, i.e., (S−s)°, the angle of elevation θ of the screw groove at a point 3 cm in the axial direction down the nearest point to the outlet port side in the region B is reduced by
3
so, i.e., (S−3s)°.
The screw groove
62
is communicated with the outlet port
17
arranged in a lower part of the exterior member
10
, so that the gas transferred through the screw groove
62
is discharged from the outlet port
17
. At the outlet port
17
, the clearance ratio d/c of the screw groove
62
is 20 or less and the angle of elevation thereof is 10 to 20°.
In the vacuum pump as such, the rotor shaft
18
is rotated at a high speed with the motor
30
to thereby rotate at a high speed the rotor
60
as well. This has process gas or the like in a chamber
90
transferred through the inlet port
16
of the screw groove type vacuum pump and through the screw groove
62
to be discharged from an outlet port
52
.
At this point, the pressure in the screw groove
62
is about 0.1 Pa or less in the region defined by the inlet port
16
and the point on the rotor
60
which is 40 mm in the axial direction (the region B), and the depth D and the angle of elevation θ of the screw groove
62
are both set to rather large values. The gas molecules are thus captured at the screw thread
63
efficiently and transferred to the outlet port
17
side without being reflected or flowing backwards.
On the side downstream of the region defined by the inlet port
16
and the point on the rotor
60
which is 40 mm in the axial direction, the pressure in the screw groove
62
is of the viscous flow region. The screw groove here changes sharply and markedly to a shallow groove and comes to have a small angle of elevation θ, which leads to efficient transfer of the captured gas molecules by viscosity to the outlet port
17
while obtaining excellent sealing.
According to this embodiment, the depth D of the screw groove
62
is 20 mm or more and the angle of elevation θ thereof is 20 to 40° at the end on the inlet port
16
side. The intake area of the gas taken in from the inlet port
16
to the screw groove
62
is therefore large, making it easy to introduce the gas into the screw groove.
According to this embodiment, in the region defined by the inlet port
16
and the point on the rotor
60
which is 40 mm in the axial direction (region B) where the pressure is about 0.1 Pa or less, the screw groove
62
has a depth D of 80% or more of the depth at the end on the inlet port
16
side and has a clearance ratio d/c of 50 or more, which together provide the groove
62
with a sufficient depth. In addition, the angle of elevation θ of the groove
62
in the region B is 80% or more of the angle at the end on the inlet port
16
side. Therefore, the gas molecules in the intermediate flow region are captured well at the screw thread
63
, and quickly transferred to the outlet port
17
side without flowing backwards.
According to this embodiment, on the side downstream of the region defined by the inlet port
16
and the point on the rotor
60
which is 40 mm in the axial direction, the screw groove changes sharply and markedly to a shallow groove and comes to have a small angle of elevation θ, which leads to efficient transfer of the gas molecules in the molecule flow region by viscosity to the outlet port
17
while obtaining excellent sealing.
According to this embodiment, at the end of the outlet port
17
, the depth D of the screw groove
62
is sufficiently shallow, the clearance ratio d/c is 20 or less, and the angle of elevation θ thereof is as sufficiently small as 10 to 20°. The back pressure dependency is thus small, which also is a contributor to obtainment of excellent gas exhaust speed.
FIG. 4
is a graph showing the relationship between the pressure and the exhaust speed in the screw groove type vacuum pump according to this embodiment, in comparison with a conventional screw groove type vacuum pump, in which the line A is associated with the screw groove type vacuum pump of this embodiment and the line B is associated with the screw groove type vacuum pump in prior art.
As shown in
FIG. 4
, in the screw groove type vacuum pump of this embodiment, the depth D and the angle of elevation θ of the screw groove
62
are set to large values in the molecule flow region and the intermediate flow region where the pressure in the screw a groove
62
is 0.1 Pa or less to thereby take in many gas molecules, introduce the gas into the screw groove without reflecting the gas or causing the backward flow of the gas, and transfer the gas molecules to the viscous flow region. Then in the viscous flow region, the depth D and the angle of elevation θ of the screw groove
62
are set to small values to secure the sealing, thereby minimizing the deterioration of the sealing and efficiently transferring the gas molecules from the intermediate flow region. Therefore, an exhaust speed better than in the screw groove type vacuum pump of the prior art can be obtained in any region of the molecule flow region, the intermediate flow region, and the viscous flow region.
The screw groove type vacuum pump structured as above is employed in an embodiment of a vacuum pump system of the present invention in which an auxiliary pump is connected to the outlet port
17
.
In the vacuum pump system according to this embodiment, the auxiliary pump may be a well-known one and, as in prior art, is connected to the outlet port
17
of the screw groove type vacuum pump.
In the vacuum pump system according to this embodiment, employment of the screw groove type vacuum pump according to the embodiment previously described makes it possible to fully utilize the capacity of the conventional auxiliary pump, so that the pressure on the outlet port
17
side is adjusted and the discharge capacity of the system is further improved.
The screw groove type vacuum pump of the present invention and the vacuum pump system of the present invention are not limited to the embodiments above, and may be modified suitably as long as the modification does not depart from the spirit of the present invention.
For instance, the depth D of the screw groove
62
of the screw groove type vacuum pump at the end on the inlet port
16
side, which is 20 mm or more in the previous embodiments, may be less than 20 mm. Because the same action and effect as in the previous embodiment can be obtained if the depth D is ¼ or more of the diameter of, including the screw groove
62
, the circumferential wall of the rotor on which the screw groove
62
is formed.
The depth D and the angle of elevation θ of the screw groove
62
are both reduced gradually at any point from the end on the inlet port
16
side to the end on the outlet port
17
side in the previous embodiment. However, the depth D and the angle of elevation θ may remain the same at some points along the path, provided that the depth and the angle are not increased at a downstream point from an upstream point. For instance, in the region defined by the inlet port
16
and the point on the rotor
60
which is 40 mm in the axial direction (region B), one of or both of the depth D and the angle of elevation θ may not be reduced but may keep the same value as the depth D and the angle of elevation θ at the end of the inlet port.
In the previous embodiment, the angle of elevation θ of the screw groove
62
is continuously reduced toward the outlet port
17
side in proportion to the distance in the axial direction on the side downstream of the region defined by the inlet port
16
and the point on the rotor body
61
which is 40 mm in the axial direction (region B in the drawing). However, the degree of this reduction may be in logarithmic proportion to the distance in the axial direction, instead. If the degree of reduction in the angle of elevation θ of the screw groove
62
is in logarithmic proportion to the distance in the axial direction, the angle of elevation θ is sharply reduced as the screw groove approaches the outlet port
17
, avoiding the influence of the back pressure even more effectively.
Though the screw groove
62
is formed on the rotor
60
in the previous embodiment, the groove may be formed on the surface of the exterior member
10
which is opposite to the rotor.
In the screw groove type vacuum pump according to the previous embodiment, the screw groove
62
is formed on the outer peripheral surface of the rotor
60
and the gas is transferred through a space between the screw groove
62
and an outer tube member that is a stator member arranged outside the groove. Alternatively, for example, an outer rotor type motor may be used to arrange the stator member inside the rotor
60
and form the screw groove
62
on the inner peripheral surface of the rotor
60
or on the outer peripheral surface of the stator member.
The same effect can be obtained in a complex vacuum pump in which the screw groove type vacuum pump according to the previous embodiment or according to the modified examples described above and a vacuum pump other than the screw groove type vacuum pump, such as a turbomolecular pump or a centrifugal flow type pump, are connected. The same effect also can be obtained in a vacuum pump system in which an auxiliary pump is provided in addition to this complex vacuum pump.
As has been described, according to the screw groove type vacuum pump, the complex vacuum pump and the vacuum pump system of the present invention, the intake area of the gas that is taken from the inlet port into the screw groove is large and the gas is hardly reflected, so that the gas is efficiently introduced from the inlet port into the screw groove and the introduced gas is transferred to the outlet port with excellent sealing properties. A high exhaust speed thus can be obtained.
Claims
- 1. A screw groove-type vacuum pump comprising: a rotor member mounted for undergoing rotation; a stator member coaxial with the rotor member and having a peripheral wall disposed opposite to and spaced-apart from a circumferential wall of the rotor member; an inlet port for introducing gas into a space between the circumferential wall of the rotor member and the peripheral wall of the stator member; an outlet port for discharging gas introduced into the space between the circumferential wall of the rotor member and the peripheral wall of the stator member; and a screw groove formed on one of the circumferential wall of the rotor member and the peripheral wall of the stator member for transferring gas introduced into the inlet port through the space between the circumferential wall of the rotor member and the peripheral wall of the stator member and to the outlet port during rotation of the rotor member; wherein a depth of the screw groove at a point thereof which is nearest the inlet port is 20 mm or more and decreases toward the outlet port from the inlet port, the depth of the screw groove in a given region defined between the point of the screw groove nearest the inlet port and a point on the rotor member disposed in an axial direction thereof at a distance of 40 mm from the point of the screw groove nearest the inlet port being 80% or more of the depth of the screw groove at the point thereof nearest the inlet port; and wherein an angle of elevation of the screw groove with respect to a radial axis of the rotor member decreases toward the outlet port from the inlet port, and the angle of elevation of the screw groove in the given region is 80% or more of the angle of elevation of the screw groove at the point thereof nearest the inlet port.
- 2. A screw groove-type vacuum pump as claimed in claim 1; wherein the depth of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 3. A screw groove-type vacuum pump as claimed in claim 1; wherein the angle of elevation of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 4. A screw groove-type vacuum pump as claimed in claim 1; wherein the angle of elevation of the screw groove decreases toward the outlet port in logarithmic proportion to the distance of the screw groove in the axial direction.
- 5. A complex vacuum pump comprising a screw groove-type vacuum pump as claimed in claim 1.
- 6. A vacuum pump system comprising: a complex vacuum pump as claimed in claim 5; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port of the screw groove-type vacuum pump.
- 7. A vacuum pump system comprising: a screw groove-type vacuum pump as claimed in claim 1; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port.
- 8. A screw groove-type vacuum pump comprising: a rotor member mounted for undergoing rotation; a stator member coaxial with the rotor member and having a peripheral wall disposed opposite to and spaced-apart from a circumferential wall of the rotor member; an inlet port for introducing gas into a space between the circumferential wall of the rotor member and the peripheral wall of the stator member; an outlet port for discharging gas introduced into the space between the circumferential wall of the rotor member and the peripheral wall of the stator member; and a screw groove formed on one of the circumferential wall of the rotor member and the peripheral wall of the stator member for transferring gas introduced into the inlet port through the space between the circumferential wall of the rotor member and the peripheral wall of the stator member and to the outlet port during rotation of the rotor member; wherein a depth of the screw groove decreases toward the outlet port from the inlet port, the depth of the screw groove at a point thereof which is nearest the inlet port being equal to or larger than ¼ the diameter of one of the circumferential wall of the rotor member and the peripheral wall of the stator member, and the depth of the screw groove in a given region defined between the point of the screw groove nearest the inlet port and a point on the rotor member disposed in an axial direction thereof at a distance of 40 mm from the point of the screw groove nearest the inlet port being 80% or more of the depth of the screw groove at the point thereof nearest the inlet port; and wherein an angle of elevation of the screw groove with respect to a radial axis of the rotor member decreases toward the outlet port from the inlet port, and the angle of elevation of the screw groove in the given region is 80% or more of the angle of elevation of the screw groove at the point thereof nearest the inlet port.
- 9. A screw groove-type vacuum pump as claimed in claim 8; wherein the depth of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 10. A screw groove-type vacuum pump as claimed in claim 8; wherein the angle of elevation of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 11. A screw groove-type vacuum pump as claimed in claim 8; wherein the angle of elevation of the screw groove decreases toward the outlet port in logarithmic proportion to the distance of the screw groove in the axial direction.
- 12. A complex vacuum pump comprising a screw groove-type vacuum pump as claimed in claim 8.
- 13. A vacuum pump system comprising: a complex vacuum pump as claimed in claim 12; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port of the screw groove-type vacuum pump.
- 14. A vacuum pump system comprising: a screw groove-type vacuum pump as claimed in claim 8; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port.
- 15. A screw groove-type vacuum pump comprising: a casing having an inlet port into which a gas is introduced and an outlet port from which the gas is discharged; a rotor member rotatably received in the casing so that a first axial end of the rotor member is disposed proximate the inlet port and a second axial end opposite the first axial end is disposed proximate the outlet port; a motor disposed in the casing for rotatably driving the rotor member; a stator member disposed in the casing and having a peripheral wall disposed opposite to and spaced-apart from a peripheral wall of the rotor member; and a screw groove formed on one of the peripheral wall of the rotor member and the peripheral wall of the stator member so that rotational movement of the rotor member causes a gas introduced at the inlet port to be transported by the screw groove in an axial direction of the rotor member away from the inlet port and toward the outlet port; wherein a depth of the screw groove at a point thereof which is nearest the inlet port is equal to or larger than ¼ the diameter of one of the peripheral wall of the rotor member and the peripheral wall of the stator member.
- 16. A screw groove-type vacuum pump as claimed in claim 15; wherein the depth of the screw groove in a given region defined between the point of the screw groove nearest the inlet port and a point on the rotor member disposed in an axial direction thereof at a distance of 40 mm from the point of the screw groove nearest the inlet port is 80% or more of the depth of the screw groove at the point thereof nearest the inlet port.
- 17. A screw groove-type vacuum pump as claimed in claim 16; wherein an angle of elevation of the screw groove with respect to a radial axis of the rotor member decreases toward the outlet port from the inlet port; and wherein the angle of elevation of the screw groove in the given region is 80% or more of the angle of elevation of the screw groove at the point thereof nearest the inlet port.
- 18. A screw groove-type vacuum pump as claimed in claim 17; wherein the angle of elevation of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 19. A screw groove-type vacuum pump as claimed in claim 17; wherein the angle of elevation of the screw groove decreases toward the outlet port in logarithmic proportion to the distance of the screw groove in the axial direction.
- 20. A screw groove-type vacuum pump as claimed in claim 15; wherein the depth of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 21. A complex vacuum pump comprising a screw groove-type vacuum pump as claimed in claim 15.
- 22. A vacuum pump system comprising: a complex vacuum pump as claimed in claim 21; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port of the screw groove-type vacuum pump.
- 23. A vacuum pump system comprising: a screw groove-type vacuum pump as claimed in claim 15; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port.
- 24. A screw groove-type vacuum pump comprising: a casing having an inlet port into which a gas is introduced and an outlet port from which the gas is discharged; a rotor member rotatably received in the casing so that a first axial end of the rotor member is disposed proximate the inlet port and a second axial end opposite the first is disposed proximate the outlet port; a motor disposed in the casing for rotatably driving the rotor member; a stator member disposed in the casing and having a peripheral wall disposed opposite to and spaced-apart from a peripheral wall of the rotor member; and a screw groove formed on one of the peripheral wall of the rotor member and the peripheral wall of the stator member so that rotational movement of the rotor member causes a gas introduced at the inlet port to be transported by the screw grooves in an axial direction of the rotor member away from the inlet port and toward the outlet port; wherein a depth of the screw groove at a point thereof which is nearest the inlet port is 20 mm or more.
- 25. A screw groove-type vacuum pump as claimed in claim 24; wherein the depth of the screw groove in a given region defined between the point of the screw groove nearest the inlet port and a point on the rotor member disposed in an axial direction thereof at a distance of 40 mm from the point of the screw groove nearest the inlet port is 80% or more of the depth of the screw groove at the point thereof nearest the inlet port.
- 26. A screw groove-type vacuum pump as claimed in claim 25; wherein an angle of elevation of the screw groove with respect to a radial axis of the rotor member decreases toward the outlet port from the inlet port; and wherein the angle of elevation of the screw groove in the given region is 80% or more of the angle of elevation of the screw groove at the point thereof nearest the inlet port.
- 27. A screw groove-type vacuum pump as claimed in claim 26; wherein the angle of elevation of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 28. A screw groove-type vacuum pump as claimed in claim 26; wherein the angle of elevation of the screw groove decreases toward the outlet port in logarithmic proportion to the distance of the screw groove in the axial direction.
- 29. A screw groove-type vacuum pump as claimed in claim 24; wherein the depth of the screw groove decreases toward the outlet port in proportion to the distance of the screw groove in the axial direction.
- 30. A complex vacuum pump comprising a screw groove-type vacuum pump as claimed in claim 24.
- 31. A vacuum pump system comprising: a complex vacuum pump as claimed in claim 30; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port of the screw groove-type vacuum pump.
- 32. A vacuum pump system comprising: a screw groove-type vacuum pump as claimed in claim 24; and an auxiliary pump connected to the outlet port of the screw groove-type vacuum pump for taking in gas discharged through the outlet port.
US Referenced Citations (2)
Number |
Name |
Date |
Kind |
4708586 |
Sawada et al. |
Nov 1987 |
A |
6217278 |
Shiokawa et al. |
Apr 2001 |
B1 |
Foreign Referenced Citations (1)
Number |
Date |
Country |
403168388 |
Jul 1991 |
JP |