RU2168070C2 - Molecular vacuum pump - Google Patents

Abstract

FIELD: technological plants for pumping and maintaining vacuum at residual pressure of 10^-1 to 10^-2 Pa. SUBSTANCE: pump housing has holes for communication with atmosphere and with cavity to be evacuated. Rotor is mounted in housing at radial and axial clearances. Outer surface of rotor is provided with helical grooves over entire length; these grooves form flow section with at least two evacuation stages located between these holes. Grooves are made in form of multistart thread. Minor diameter of thread increases on suction side from holes communicated with cavity being evacuated towards discharge end to holes communicated with atmosphere. Shaft is located in axial hole; ends of this shaft are rigidly connected with housing. Radial clearance between shaft and hole is used as gas-dynamic support for rotor. EFFECT: reduced mass and overall dimensions of pump with no change in pumping speed and degree of gas compression. 9 cl, 2 dwg

Description

 The present invention relates to vacuum technology, relates to rotary pumps of continuous displacement for gases or vapors, namely molecular vacuum pumps.

The proposed molecular vacuum pump can be used in various technological installations to create and maintain a vacuum with a residual gas pressure of 10 ^-1 to 10 ^-2 Pa, for example, in electronics in the manufacture of microcircuits, in the growth of crystals, as well as in various research facilities and devices which operate using vacuum, for example, in particle accelerators, in mass spectrometers, electron microscopes, leak detectors, and in fusion reactors for pumping tritium-containing media.

 A large number of molecular vacuum pumps are known having various pumping characteristics, in particular, the degree of compression, the speed of action and the ultimate residual gas pressure.

 The principle of operation of the molecular vacuum pump is that the molecules of the pumped gas in a collision with the rotating surface of the rotor are involved in the movement along the screw channels of the flow part of the pump from the inlet, from the suction side, to the outlet, to the discharge side.

 The pumping characteristics of the molecular vacuum pump mainly depend on the length of the gas evacuation channels and the ratio of the passage area of the channel, depending on the depth of the grooves at its inlet and outlet, the rotor speed, and the clearance of the pump passage.

Known molecular vacuum pump (see application PCT / SU88 / 00001), in the housing of which is located a rotor, on the outer surface of which there are grooves located along helical lines, essentially along the entire length of the rotor, forming channels of the flowing part with the inner surface of the housing. The pump also has a shaft located along the axis of the rotor, one end of which is rigidly connected to the rotor, and the other is mounted in sliding bearings and connected to an electric motor that drives it into rotation. The pressure at the inlet of the flowing part of such a pump can be from 10 ^-1 to 10 ^-7 Pa, and the pressure at the outlet is 10 Pa. Such a pump cannot work for the atmosphere, it is connected to a foreline pump. When the outlet is connected to the atmosphere, such a pump is not operable, since a significant backflow of gas occurs in the flow part, since in the entire flow part the gap between the outer surface of the rotor and the inner surface of the housing exceeds the depth of the helical grooves. With such a constructive connection of the rotor with the electric motor, the beat of the rotor axis during rotation exceeds a value that is permissible for the size of the gap of the flowing part, in which there is essentially no back flow of gas dispersion. The size of such a gap can be commensurate with the mean free path of the molecules of the pumped gas and can be from 20 to 30 μm, and the beating of the axis of the rotor can range from 0.5 to 1 μm. Such accuracy can provide gas-static supports, widely used in molecular vacuum pumps.

 Known molecular vacuum pump, with gas-static bearings of the rotor, which operates at atmospheric pressure, (see patent RU N 2016255 C1 from 23.08.90).

 In such a molecular vacuum pump in a housing having openings designed to communicate with the atmosphere and with a vacuum cavity, there is a rotor mounted with radial and axial clearances, one end of which is adapted to communicate with an electric motor and on the outer surface of which there are screw grooves forming a flow a part with at least two stages of pumping, located between these holes, made in the form of multiple threads, the inner diameter of which increases on the whole side pressure, from the hole designed to communicate with the evacuated cavity, in the direction of discharge, to the hole designed to communicate with the atmosphere.

 The rotor is a shaft, on one half of which helical grooves are made along the length, and the other half of the rotor is smooth. The outer diameter of both parts of the rotor is essentially the same. These parts of the rotor are separated by an annular portion of a smaller diameter associated with thread cutting technology. For communication with the electric motor, the end is adapted from the side of the smooth part of the rotor.

 For communication with the evacuated cavity, an axial hole is made at the end of the housing. The rotor is installed in the housing so that the free end of the rotor faces the axial hole, on the side on which the helical grooves are made. The holes intended for communication with the atmosphere are made in the housing in its middle part and are located radially at the level of the technological groove. Thus, the length of the flow part along the axis of the pump located between these holes is about half the length of the rotor. In this case, the other part of the rotor, with a smooth outer surface, forms with the inner surface of the housing a radial sliding support of the rotor.

This sliding support is a gas-static support, it is necessary to supply compressed air to it under pressure from 4 • 10 ⁵ to 5 • 10 ⁵ Pa. To supply compressed air to this support in the housing there are channels, which requires an increased thickness of the walls of the housing. In this case, the gap serving as a radial gas-static support is directly connected with the flow part, being its continuation. In this case, the flow of evacuated gas from the flow part and the gas flow from the sliding support are directed towards each other and exit the cavity of the housing through the same openings in communication with the atmosphere. At the outlet of the gas-static support, the gas flow has an excess pressure of 240 Pa, which reduces the pressure drop in the flow part, and, consequently, the compression ratio of the pump.

 With such a constructive implementation of the pump, its flow part, on the extent of which the pumping characteristics depend, is located no more than half the length of its rotor, which significantly increases the weight of the pump and its length.

 In addition, the thermal mode of operation of such a pump is quite intense, which significantly reduces pumping characteristics and requires water cooling.

 The need to constantly supply compressed air to the gas-static supports of the pump reduces the reliability of the vacuum pump and complicates its operating conditions.

 The basis of the invention is the task of creating a molecular vacuum pump with such a design and arrangement of sliding bearings of the rotor and the pump passage, at which the weight and dimensions of the pump for a given speed of action and degree of compression of the gas are reduced and at the same time its design is simplified, reliability and durability are improved service.

 The problem is solved in that the molecular vacuum pump, in the casing of which has holes designed to communicate with the atmosphere and with the evacuated cavity, is a rotor mounted with radial and axial clearances, one end of which is adapted for communication with the electric motor and on the outer surface of which there are screw grooves forming a flow part with at least two stages of pumping, located between these holes, made in the form of multiple threads, inner diameter which increases on the suction side, from the holes intended for communication with the evacuated cavity, to the pressure side, to the holes intended for communication with the atmosphere, according to the invention comprises a shaft, ends rigidly connected to the housing and installed in the axial hole made in the rotor with a radial clearance which serves as the gas-dynamic support of the rotor and is in communication with the flow part from the discharge side through an axial clearance, while the grooves of the flow part are located essentially over the entire length of the mouth ora.

 Such a constructive implementation of the proposed molecular vacuum pump allows, in comparison with the known pump having the same pumping characteristics, to reduce its dimensions and weight by at least two times.

 In addition, simplifying the design of the pump increases its reliability and service life.

 It is advisable that, according to the invention, the flow part of the molecular vacuum pump has two pumping stages, in each of which the angle of inclination of the internal diameter of the thread is constant, while the angle of inclination of the thread of the first stage, located on the suction side, is greater than the angle of inclination of the thread of the second stage, located with side of the discharge, and the length of the first stage ranged from 0.25 to 0.6 of the length of the rotor, on which the grooves of the flow part are made.

 In the molecular vacuum pump according to the invention, the ratio of the depth of the grooves at the ends of the first stage of the flow part can range from 20 to 100.

 To increase the reliability of operation, the molecular vacuum pump according to the invention on the outer surface of the shaft may have grooves of gas-dynamic bearings located along helical lines in the form of multiple threads.

 According to the invention, the grooves of the gas-dynamic support can be made on the annular sections of the outer surface of the shaft with the thread direction of the adjacent sections in one or in opposite directions.

 According to the invention, between adjacent regions with grooves of the gas-dynamic support, there may be regions with a smooth outer surface.

 In order to eliminate the axial loads acting on the rotor and increase the reliability of operation, in the molecular vacuum pump according to the invention, the openings for communicating with the evacuated cavity are located in the middle part of the housing, and the openings for communicating with the atmosphere are located on the side of the housing the end of the rotor, adapted for communication with the electric motor, while in the case there are additional openings designed to communicate with the atmosphere, which are located at its other end, n and at the same distance from the holes located in the middle part, as the main holes intended for communication with the atmosphere, and on the outer surface of the rotor between the holes located in the middle part and additional holes grooves are made in the form of multi-thread, essentially similar to the main grooves, but having an opposite thread direction, forming an additional flow part, with a pumping direction opposite to the pumping direction of the main flow part.

 To simplify the design and increase reliability and service life, the molecular vacuum pump according to the invention may include a magnetic support for maintaining axial clearance between the housing and the rotor located at the other end of the rotor and containing coaxially located ring and disk or cylinder made of hard magnetic material, while the disk or the cylinder is rigidly connected to the shaft, and the ring to the rotor.

 To increase the speed of action in the molecular vacuum pump according to the invention, on the inner surface of the housing there are grooves in the form of multi-thread, located along the length of the main and additional flow parts and made similar to grooves on the outer surface of the rotor, while the thread direction on the housing of the corresponding flow part is opposite to the thread direction on the rotor.

The invention is further explained in the description of a specific variant of its implementation and the accompanying drawings, in which:
FIG. 1 shows a molecular vacuum pump with one flow part (longitudinal section) according to the invention;
FIG. 2 - molecular vacuum pump with two flow parts, (longitudinal section with a partial section of the rotor shaft at the location of the magnetic support) according to the invention.

 The proposed molecular vacuum pump contains a housing 1 (Fig. 1), consisting of a cylinder 2 with end caps 3 and 4.

 In the cylinder 2 there are two groups of holes 5 and 6, which are located at different ends of the cylinder 2. Holes 5 are designed to communicate with the evacuated cavity and are located on the end of the cylinder 2 from the side of the end cover 3. Holes 6 are designed to communicate with the atmosphere and are located on the other its end, from the side of the end cover 4.

 The number of holes 5 or 6 in each group can be from three to eight. The axis of the holes 5 and 6 in each group in the one shown in FIG. 1 embodiment of the pump are arranged radially, essentially in the same plane at the same distance from one another around the circumference. The diameter of the holes 5 or 6 is at least 3 mm. The number of holes 5 and 6 in each group, their diameter can be different, they are selected depending on the speed of the pump, the higher the speed of action, the greater the number and diameter of holes 5 and 6.

 A rotor 7 is located in the casing 1 of the molecular vacuum pump. The rotor 7 is installed in the casing 1 essentially freely, the radial clearance e between the inner surface of the cylinder 2 and the outer surface of the rotor 7 can be from 10 to 15 μm. At e greater than 15 μm, a reverse gas flow into the evacuated cavity is possible, which reduces the pumping characteristics of the pump. A gap e of less than 10 μm is technologically difficult to maintain.

 On the outer surface of the rotor 7 there are grooves 8 forming a flow part P communicated through openings 5 and 6 with the evacuated cavity and the atmosphere, respectively. The grooves 8 are located along helical lines in the form of multiple threads along substantially the entire length of the rotor 7. In this case, one of the end surfaces of the rotor 7 is located in close proximity to one of the planes in which the axes of one of the groups of holes 5 or 6 lie.

 The internal diameter of the thread increases, and the depth of the grooves 8 decreases on the suction side, from the holes 5, intended for communication with the evacuated cavity, in the discharge direction, to the holes 6, designed for communication with the atmosphere. In this case, the total flow cross-section of holes 5 and 6 in each group is selected from the condition that there is no back-up of gas leaving the flow part P of the pump through holes 6.

 The rotor 7 of the proposed molecular vacuum pump is made essentially hollow, it has an axial hole 9.

 The pump also contains a shaft 10, the ends rigidly connected, for example, by means of a tight fit, with the end caps 3 and 4 of the housing 1. The shaft 10 is located in the axial hole 9 of the rotor 7 and is installed in it with a gap ε, which during rotation serves as a support for the sliding of the rotor 7. The annular gap ε between the outer surface of the shaft 10 and the surface of the hole 9 of the rotor 7 is a radial gas-dynamic support of the rotor 7 and, when they are coaxial, can lie in the range from 1 to 15 μm, respectively, the diameter of the shaft 10 can be less than the diameter of the hole 9 by from 2 to 30 microns.

 The diameter of the hole 9 may be from 0.25 to 0.5 of the outer diameter of the rotor 7. The diameter of this hole 9 is selected taking into account the requirements for a radial gas-dynamic support, for example stiffness. As is known, the radial clearances of sliding bearings, which serve as gas-dynamic supports, can be from 1 to 15 μm or more, depending on the diameter of the shaft, and, unlike the gas-static support, they do not need to supply compressed gas. A gap ε of less than 1 μm is not advisable to choose, since the technology of manufacturing the support is complicated. With a gap ε greater than 15 μm, the bearing capacity of the gas-dynamic support decreases. In the described embodiment of the pump, the radial clearance ε lies in the range from 3 to 5 μm.

The length and execution of the grooves forming the flow part of the pump, that is, the structural parameters of the thread, mainly determine the pumping characteristics of the molecular vacuum pumps and, therefore, their dimensions: length and diameter. The length of the rotor, essentially equal to the length of the flow part along the axis of the proposed pump, determines the length of its housing. In this case, the rotor diameter, which sets the length of the flow part along the helix, is selected so that the rotor length is not less than the diameter. The outer diameter of the housing 1 of the proposed molecular vacuum pump, for example, for a speed of 20 m ³ / min and a compression ratio of 10 ⁶ - 10 ⁸ , can be about 100 mm and a length of about 190 mm. The length and weight of such a pump is reduced by at least two times the length and weight of the known pump.

The grooves of the flow part can be made as in the known molecular vacuum pumps. The angle of inclination of the thread can be from 15 ^o to 25 ^o and can be either constant or variable along the length of the rotor. The thread profile is predominantly rectangular. The width of the grooves and the width of the jumpers between them can be either the same or vary along the length of the flow part. In the pump embodiment shown in FIG. 1, the grooves 8 have the same width, which can be about 1 mm when threading, the width of the jumpers is equal to the width of the grooves 8. The thread profile can be not only rectangular, but also different, for example, trapezoidal.

The internal diameter of the thread forming the flow part P can vary, as in other similar pumps, both smoothly and stepwise, while the flow part P can contain two or more pumping stages. In the pump embodiment shown in FIG. 1, the flow part P has two pumping stages S ₁ and S ₂ . At the first stage, S ₁ is the molecular regime of gas flow; at the second stage, S ₂ is viscous. In each of the steps S ₁ and S _{2, the} corresponding angle α ₁ and α _{2 of the} inclination of the internal diameter of the thread is constant. The angle α _{1 of the} inclination of the internal diameter of the thread of the first stage S ₁ communicated with the evacuated cavity is greater than the angle α _{2 of the} inclination of the internal diameter of the thread of the second stage S ₂ communicated with the atmosphere α ₁ , α ₂ .
The magnitude of the angles α ₁ and α ₂ depends on the length of the steps S ₁ and S ₂ , the depth k ₁ , k ₂ , k ₂ ¹ grooves 8 at the ends of these steps S ₁ and S ₂ .

The length of the flow part P along the axis of the rotor 7 is selected depending on the required speed of action and degree of compression, it is equal to the total length of both stages S ₁ + S _{2 of the} pump. Since the helical grooves 8 forming the flow part P are made substantially along the entire length of the rotor 7, the total length of both steps S ₁ + S ₂ is substantially equal to the length of the rotor 7. The length of the first step S ₁ can be from 0.25 to 0.6 the length of the rotor 7, on which the grooves 8 of the flow part P are made. For greater speed of action, the length S ₁ is selected more. For a greater degree of compression, the length S ₁ is selected less. As shown in FIG. 1 of the pump, the length of the first stage S ₁ is 0.25 of the length of the rotor 7.

The depth k ₁ , k ₂ , k ₂ ^{1 of the} grooves 8 and, accordingly, the values of the inclination angles α ₁ and α ₂ and the length of the steps S ₁ and S ₂ depend on the mean free path of the molecules of the pumped gas, which changes in accordance with the change in the gas pressure in flow part P of the pump. For example, at a pressure of 10 ^-1 Pa, the mean free path of nitrogen molecules is 67 mm. The depth k ₁ , k _{2 of the} grooves 8 of the first molecular stage of pumping is selected experimentally, depending on the mean free path of the molecules of the pumped gas, it should be comparable with the mean free path of the molecules of the pumped gas. The depth k _{1 of the} grooves 8 at the beginning of the first stage S _{1 of the} flow part P from the side communicated with the evacuated cavity, in which the residual gas pressure is about 10 ^-1 Pa, can lie in the range from 3 to 10 mm. For a lower residual pressure, the depth of the grooves 8 is chosen greater.

The depth k _{2 of the} grooves 8 at the end of the first stage S ₁ depends on the length of the first stage S ₁ and the compression ratio. The ratio of the depth k ₁ and k _{2 of the} grooves 8 at the ends of the first stage can be from 20 to 100, since the mean free path of the molecules of the pumped gas at the degree of gas compression at the ends of the first stage S ₁ , which is a molecular stage, can differ from 20 to 100 times . Moreover, the smaller the length S _{1 of the} first stage, the greater this ratio. For example, in the embodiment shown in FIG. 1, the ratio of k ₁ to k ₂ may be 50.

The depth k _{2 of the} grooves 8 at the end of the first stage S ₁ can be from 80 to 100 microns. The depth of the grooves 8 at the beginning of the second stage S ₂ is equal to the depth k _{2 of the} grooves 8 at the end of the first stage S _{1 of the} flow part P. The depth k ₂ ^{1 of the} grooves 8 at the end of the second stage S ₂ , that is, from the side of the pump flow part P connected to the atmosphere may be from 20 to 25 microns.

To increase the reliability of the molecular vacuum pump in the nominal mode at rotor speeds of more than 20,000 rpm, on the outer surface of the shaft 10 there are grooves 11 of the gas-dynamic support located along helical lines in the form of a multi-thread. The grooves 11 serve to prevent the appearance of a half-speed vortex in the support, which at rotational speeds of more than 20,000 rpm can lead to the destruction of the gas-dynamic support. The angle of the thread of the grooves 11 of the gas-dynamic support can be from 18 ^o to 60 ^o . The depth of the grooves 11 is the same, it can be from 1 to 15 μm, and depending on the size of the gap ε can be from 0.5 to 1 ε. The depth of the grooves 11 of less than 1 μm is not effective, and with a depth of more than 15 μm, the necessary bearing capacity of the gas-dynamic support is not provided.

The grooves of the gas-dynamic support can be made both along the entire length of the shaft, and on separate annular sections, of the same or different widths, with the threading of adjacent sections both in one or in opposite directions. The width of the annular sections with grooves of the gas-dynamic support can be from 0.2 to 0.5 of the length of the rotor. Between adjacent annular portions having threaded grooves, annular portions with a smooth outer surface can be arranged. The choice of a specific embodiment of the location and execution of the gas-dynamic support sections depends on many factors, in particular, on the design of the pump, for example, the location of the openings communicated with the evacuated cavity or its working conditions, for example, dust content. In the ε embodiment shown in FIG. 1, the pump grooves 11 are formed on the shaft 10 in three annular sections 12,13,14. Between sections 13 and 14 is an annular section 15 with a smooth outer surface. In sections 13 and 14, the helical lines along which the grooves 11 are located are directed in one direction, and in section 12, in the other. The adjacent sections 12 and 13, 13 and 15, 14 and 15 are separated by annular grooves, respectively, t ₁ , t ₂ and t ₃ , the presence of which is associated with the technology of threading. The size of the annular gap formed by these grooves is greater than ε. The direction of the thread in sections 12, 13, 14 depends on a given direction of gas circulation in the gas-dynamic support and is selected depending on the direction of rotation of the rotor 7 (shown in Fig. 1 by the arrow ω). In sections 13 and 14, the thread is right, and in section 12, the left. The thread in section 14 is made right to seal the evacuated cavity, the direction of the thread in sections 12 and 13 to the groove t ₁ increases the efficiency of the gas-dynamic support. To supply gas to the gap ε, the shaft 10 has an axial channel 16 connected to each other, connected to the atmosphere, and a radial channel 17, connected to the gap ε.
To fix the axial position of the rotor 7, it has an axial gas-dynamic support. This support is the gaps b ₁ and b ₂ between the annular protrusion 18, made on the end of the shaft 10, located on the side of the end cover 4, the washer 19 and the surface of the groove 20 made in the rotor 7. The washer 19 is rigidly connected with the rotor 7. On the end surfaces the protrusion 18 there are spiral grooves of the gas-dynamic supports (not shown), made in a known manner.

 The direction of the thread on the rotor 7 also depends on the choice of the direction ω of its rotation. As shown in FIG. 1 version of the pump on the rotor 7 left thread.

 One end of the rotor 7 is adapted for communication with an electric motor that drives it into rotation. As an electric motor, any electric motor can be used, for example a valve or hysteresis one. In the embodiment shown in the drawing, a valve electric motor is used, the stator winding 21 of which is mounted in the cover 4 of the housing 1, and the rotor of the electric motor contains cylindrical elements 22 of hard magnetic material, which are permanent magnets that are installed in the holes made in the washer 19.

The annular gaps e and e, that is, the flow part P and the radial gas-dynamic support of the rotor 7, in the idle state of the pump, when the rotor 7 is stationary, are communicated to each other from the free end of the rotor 7, that is, from the suction side, through an axial clearance c ₁ between the cover 3 and the end surface of the rotor 7, and on the side of its end connected with the electric motor, i.e., on the discharge side, through the axial clearance c ₂ between the cover 4 and the other end surface of the washer 19. The magnitude of these gaps c ₁ and c ₂ can be from 3 to 5 mm or more.

 Outside, at the location of the holes 5, the cylinder 2 of the housing 1 is surrounded by a ring 23 with a flange 24, designed for docking with a vacuum cavity (not shown). There is a hole 25 in the flange 24 and the ring 23 is positioned so that the axis of the hole 25 is substantially aligned with the axis of one of the holes 5. The remaining holes 5 are overlapped by the ring 23. On the outer surface of the cylinder 2 at the location of the holes 5 and on the inner surface of the ring 23 made annular grooves, which are aligned with each other, forming an annular cavity 26, communicated through the hole 25 with the evacuated cavity.

In the embodiment shown in FIG. 2, the molecular vacuum pump according to the invention is presented, the diameter of which is compared to the pump with the same speed of action shown in FIG. 1, reduced by at least 1.5 times. In this pump, two - the main and additional flow parts P ₁ and P ₂ are located between the inner surface of the cylinder 27 of the housing 1 and the outer surface of the installed rotor 28.

 The housing 1 also has end caps 29 and 30, rigidly connected with the cylinder 27.

In the middle part of the cylinder 27, openings 31 are provided for communicating the flow parts P ₁ and P _{2 of the} pump with a vacuum cavity. The holes 31 are located radially at the same distance from each other around the circumference. The number of holes 31 may be any, but it is most expedient, as in the one shown in FIG. 1 version of the pump, to perform from three to eight holes 31.

In the housing 1, at opposite ends of the cylinder 27, at substantially the same distance along the openings 31, there are two groups of radially arranged openings 32 and 33 for communicating the flow parts P ₁ and P _{2 of the} pump with the atmosphere.

The number of holes 32 and 33 in each group can be from three to eight, their diameter is at least 3 mm. In this case, the total flow cross-section of the holes 31, 32 and 33 in each group is selected from the condition that there is no back-up gas leaving the flow parts P ₁ and P _{2 of the} pump, respectively, through the holes 32 and 33. For example, with the same number of holes 31, 32 and 33 in each group, and the same diameter of the holes 32 and 33, the diameter of the holes 31 should be twice the diameter of the holes 32 and 33.

On the outer surface of the rotor 28, grooves 34 and 35 are made, forming the main and additional flowing parts P ₁ and P ₂ . In this case, the grooves 34 of the main flow part P ₁ can be made similarly to the grooves 8 of the flow part P of the molecular vacuum pump shown in FIG. 1. The grooves 35 of the additional flow part P _{2 are} made essentially similar to the grooves 34 of the main flow part P ₁ but have the opposite thread direction to set the pumping direction in the additional flow part P ₂ in the direction opposite to the pump direction in the main flow part P ₁ . Moreover, the length of the main flow part P ₁ is equal to the length of the additional flow part P ₂ and is S ₁ ¹ + S ₂ ¹ that is, equal to the total length of both pumping stages.

In the pump embodiment shown in FIG. 2, the length of the first stage S ₁ ¹ is 0.6 of the length of the rotor 28, on which grooves 34 or 35 of the main or additional flow part P ₁ or P _{2 are made} , that is, S ₁ ¹ is 0.6 ( S ₁ ¹ + S ₂ ¹ ), which provides the maximum compression ratio.

The ratio of the depth of the grooves 34 or 35 at the ends of the first stage S ₁ ^{1 of the} main or additional flow part P ₁ or P _{2 is} chosen equal to 20, since the length S ₁ ^{1 is} selected maximum.

 The helical lines along which the grooves 34 and 35 are located are directed in different directions to form two oppositely directed flows of the evacuated gas - one from hole 31 to holes 32, and the other from the same holes 31 to holes 33.

 An advantage of such a design of the vacuum pump is the separation of the pumped gas into two oppositely directed flows, with virtually no axial force acting on the rotor 28. In the known pump and in the pump shown in FIG. 1, this axial force can be, for example, for a rotor with a diameter of 65 mm about 300 H.

 In the proposed molecular vacuum pump for fixing the axial position of the rotor can be installed magnetic support. The use of a magnetic support instead of the axial gas-dynamic support used in the pump embodiment of FIG. 1, which is subject to significant axial loads, can improve the reliability of the pump and its service life. Moreover, the stiffness of the magnetic support used in the proposed pump is not high, since there is no axial force and the weight of the rotor compared to the known pump is reduced by at least two times. The magnetic support allows you to reliably center on the axis of the housing 1 of the rotor 28, which has a greater length compared with the rotor 7 (Fig. 1).

 The rotor 28 (Fig. 2) is made with an axial hole 36. A shaft 37 is installed in this hole 36, the ends are rigidly connected with the end caps 29 and 30. On the outer surface of the shaft 37 there are grooves 38 in the form of multi-thread, forming a radial gas-dynamic support of the rotor 28 , which can be performed as in the description of the pump shown in FIG. 1.

 The magnetic support in the proposed molecular pump comprises a ring 39 mounted in a groove made on the end face of the rotor 28 facing the end cover 29 of the housing 1, and a disk 40 mounted in the bore of the shaft 37 of the rotor 28, and preloaded by the plug 41. The elements of the magnetic support are made of hard magnetic materials used as permanent magnets.

 With the large dimensions of the rotor to create a stronger magnetic field, you can install a cylinder (not shown) in the shaft bore 37.

In the embodiment of the pump shown in FIG. 2, the helical grooves 39 of the gas-dynamic support are made on four annular sections 42,43,44,45 of the shaft 37 having the same width. Between adjacent annular sections 42 and 43, 43 and 44, 44 and 45 with grooves 39, respectively, an annular section 46, 47, 48 with a smooth outer surface. The outer diameter of the annular sections 42, 43, 46 and 44, 48, 45, forming a gas-dynamic support, the same, the gap ε ¹ between the shaft 37 and the hole 36 of the rotor 28 can be from 1 to 15 microns. The outer diameter of the annular section 47 of the shaft 38 is smaller than the outer diameter of the annular sections 42, 43, 46 and 44, 48, 45, with a gap ε $\genfrac{}{}{0ex}{}{\text{1}}{\text{1}}$ is from 20 to 30 microns. To communicate the gas-dynamic support with the atmosphere, the shaft 37 has two radial channels 49 and 50 communicated with each other by an axial channel (not shown in the drawing).

In the proposed embodiment, the vacuum pump on the inner surface of the cylinder 27 of the housing 1 to increase the flow area of the main and additional flowing parts P ₁ and P ₂ made grooves 51 and 52 in the form of multiple threads. The grooves 51 are made similar to the grooves 34, but have, in comparison with them, the opposite direction of threading. The grooves 52 are made similar to the grooves 35, but have, in comparison with them, the opposite direction of threading. Grooves 51 and 34 form the main flow part P ₁ , and grooves 52 and 35 form the additional flow part P ₂ An increase in the flow area of the flow parts P ₁ and P ₂ increases the pumping characteristics of the pump, in particular the speed of action.

Outside, at the location of the openings 31, the cylinder 27 of the housing 1 is surrounded by a ring 53 with a flange 54 intended for docking with a vacuum cavity (not shown in the drawing). There is a hole 55 in the flange 54 and the ring 53 is positioned so that the axis of the hole 55 is substantially aligned with the axis of one of the holes 31 for communicating the flow parts P ₁ and P ₂ with the evacuated cavity. The remaining holes 31 are blocked by a ring 53. On the outer surface of the cylinder 27 at the location of the holes 31 and on the inner surface of the ring 53, annular grooves are made, which are aligned with each other, forming an annular cavity 56 communicated through the hole 55 with the evacuated cavity.

In addition, on the inner surface of the cylinder 27 at the location of the holes 31 and on the outer surface of the rotor 29 are also made annular grooves, which are aligned with each other, forming an annular cavity 57 in communication with the flowing parts P ₁ and P ₂ and through the holes 31 with the annular cavity 56.

 As shown in FIG. In the second embodiment of the pump, a valve electric motor was also used, the stator winding 58 of which is mounted in the cover 30 of the housing 1, and the rotor of the electric motor contains cylindrical elements 59 of hard magnetic material, which are permanent magnets that are installed in the holes made on the end of the rotor 28.

The flow part P ₁ and the annular gap ε ^{1 of the} radial gas-dynamic support of the rotor 28 are interconnected from the end of the rotor 28 connected to the electric motor through the axial clearance c ₂ ¹ between the cover 30 and the end surface of the rotor 28. The flow part P ₂ and the annular gap ε ¹ from its other end are communicated through an axial clearance c ₁ ¹ between the cover 29 and the other end surface of the rotor 28. The values of these gaps c ₁ ¹ and c ₂ ¹ can be from 3 to 5 mm or more.

The proposed molecular vacuum pump of FIG. 1, works as follows. The flange 24 of the ring 23 is connected to the evacuated cavity (not shown in the drawing) and the joint is sealed. Before bringing the rotor 7 into rotation in the cavity of the housing 1 — in the gaps ε, ε, b ₁ , b ₂ , c ₁ , c ₂ and channels 16 and 17, the annular cavity 26, holes 5 and 6 — the gas pressure is atmospheric. After turning on the electric motor when its stator 21 interacts with the elements 22, the pump rotor 7 is rotated at a speed of more than 20,000 rpm in the direction ω. When the rotor 7 is rotated due to viscous friction forces, the gas in the gap ε is drawn into rotation and guided by the grooves 11 of the radial gas-dynamic support in sections 12 and 13 to the groove t ₁ , creating an excess gas pressure in the gap ε, which ensures the rotor 7 is centered on the axis of the shaft 10, preventing contact of the shaft 10 and the rotor 7. The groove 11 radial gas dynamic support portion 14 on the gas is directed to the groove t _3, creating a gap ε excess gas pressure, providing along with the sealing of the gap 7, centering of the rotor ₁ c communicated with the straight exact part P on the suction side, i.e. the part of the evacuated cavity.

The gas pressure in the gaps b ₁ and b _{2 of the} axial gas-dynamic support provides a fixation of the axial position of the rotor 7. The use of the radial and axial gas-dynamic support in the proposed vacuum pump ensures its reliable operation and does not require forced supply of compressed gas to the support, as in the known pump.

In addition, in the axial clearance c ₂ , which is in communication with the gas-dynamic support and the flow part P from the discharge side, the gas pressure is equal to atmospheric. This compared with the known pump can improve the pumping characteristics of the proposed pump, in particular, to increase the compression ratio.

When the rotor 7 rotates, the gas molecules pumped out of the evacuated cavity, which enter through the hole 25, the annular cavity 26 and the holes 5 into the pump flow part P from the suction side, are captured by the surface of the grooves 8 and are involved in the movement, directing the pumped gas flow from holes 5 to holes 6, that is, from the suction side to the discharge side. In this case, the gas pressure from the suction side, that is, in the evacuated cavity, decreases to the required residual pressure, which can reach from 10 ^-1 to 10 ^-2 Pa. In the steady state operation of the pump along the length S _{1 of the} first stage, the molecular gas flow is predominantly provided in which the probability of collision of gas molecules with each other is less than the probability of their collision with grooves 8. The pressure drop over the first stage S ₁ can be from 10 ^-1 - 10 ^-2 to 10 ² Pa. On the length S _{2 of the} second stage, a viscous gas flow is predominantly provided, in which the probability of collision of gas molecules with each other is greater than the probability of their collision with grooves 8. The pressure at the end of the second stage S ₂ is 10 ⁵ Pa, i.e. equal to atmospheric. In the transition zone between S ₁ and S _{2 is the} molecular-viscosity regime of the gas flow. The return gas flow in such a flow part P is essentially absent, since the gap e is small and ranges from 10 to 15 μm. Thus, the dimensions and weight of the proposed vacuum pump compared with the known pump with the same pumping characteristics are reduced by at least two times. There is no need to supply compressed gas to the sliding bearings of the rotor.

The molecular vacuum pump shown in figure 2, operates as follows. The position of the rotor 28, both in the operating position, with the electric motor turned on, and in the idle position, with the electric motor turned off, (is fixed along the shaft axis 37 with a magnetic support due to the interaction of the ring 39 and the disk 40. When they interact, the required axial clearance value c _{1 is} maintained ¹ and c ₂ ^1, and the grooves are combined in the cylinder 27 and on the rotor 28, forming an annular cavity 57. The flange 54 of the ring 53 is connected to the evacuated cavity (not shown in the drawing) and the joint is sealed. e of the rotor 28 in the cavity of the housing 1 - in the gaps ε ¹ , ε $\genfrac{}{}{0ex}{}{\text{1}}{\text{1}}$ c ₁ ¹ , c ₂ ¹ , in the flow parts of P ₁ and P ₂ channels 49, 50, the gas pressure is atmospheric. After turning on the electric motor, the rotor 28 is rotated. When the rotor 28 rotates due to viscous friction forces, the gas in the gaps ε ¹ and ε $\genfrac{}{}{0ex}{}{\text{1}}{\text{1}}$ involved in rotation and guided by grooves 38 of the radial gas-dynamic support in sections 42 and 43 to section 46, and in sections 44 and 45 to section 48, creating excessive gas pressure over each group of sections 42,46,43 and 44,48,45, providing centering of the rotor 28 along the axis of the shaft 37, preventing contact of the rotor 28 with the shaft 37. Through channels 49 and 50, gas is supplied to the gas-dynamic support to section 47. Along section 47, the pressure is atmospheric.

When the rotor 28 rotates, the gas molecules pumped out of the evacuated cavity that enter through the hole 55, the annular cavity 56, the openings 31 into the annular cavity 57 are captured by the surface of the grooves 34 or 35. They are drawn into the movement by the grooves 34, directing the pumped gas stream along the flow part P ₁ from openings 31 to openings 33 to the atmosphere. By grooves 35, the gas molecules are involved in the movement, directing the pumped gas stream along the flow part P ₂ from the openings 31 to the openings 32 to the atmosphere. Thus, during the operation of the molecular vacuum pump shown in FIG. 2, the gas flow pumped out from the evacuated cavity is divided in the annular cavity 57 into two flows directed in opposite directions, therefore, the axial forces acting on the rotor 28, which arise due to the difference the pressures on the suction side, from the side of the openings 31, and on the discharge side, from the side of the openings 32 or 33, each flow part P ₁ and P ₂ , are balanced.

The operation of each of the flow parts P ₁ and P ₂ is essentially similar to the operation of the flow part P of the pump shown in FIG. 1, except that the presence of grooves 51 and 52 on the inner surface of the cylinder 27 of the housing 1 increases the flow area of the flow parts P ₁ and P ₂ , which improves the pumping characteristics of the pump, in particular the speed of action.

Claims (9)

 1. Molecular vacuum pump, in the housing of which there are openings designed to communicate with the atmosphere and with the evacuated cavity, there is a rotor mounted with radial and axial clearances, one end of which is adapted to communicate with an electric motor and on its outer surface there are screw grooves, forming a flow part with at least two stages of pumping, located between these holes, made in the form of multiple threads, the inner diameter of which increases from the side suction from the holes intended for communication with the evacuated cavity, in the direction of discharge to the holes intended for communication with the atmosphere, characterized in that it contains a shaft, the ends rigidly connected to the housing and installed in the axial hole made in the rotor with a radial clearance, which serves as a gas-dynamic the support of the rotor and is in communication with the flow part from the discharge side through the axial clearance, while the grooves of the flow part are located essentially along the entire length of the rotor.  2. The molecular vacuum pump according to claim 1, characterized in that the flow part has two stages of pumping, in each of which the angle of inclination of the inner diameter of the thread is constant, while the angle of inclination of the thread of the first stage, located on the suction side, is greater than the angle of inclination of the thread of the second a stage located on the discharge side, and the length of the first stage is from 0.25 to 0.6 the length of the rotor, on which the grooves of the flow part are made.  3. The molecular vacuum pump according to claim 2, characterized in that the ratio of the depth of the grooves at the ends of the first stage of the flow part is in the range from 20 to 100.  4. The molecular vacuum pump according to claim 1, or 2, or 3, characterized in that on the outer surface of the shaft there are grooves of the gas-dynamic support located along helical lines in the form of a multi-thread.  5. The molecular vacuum pump according to claim 4, characterized in that the grooves of the gas-dynamic support are made on the annular sections of the outer surface of the shaft with the thread direction of the adjacent sections in one or in opposite directions.  6. The molecular vacuum pump according to claim 5, characterized in that between adjacent sections with grooves of the gas-dynamic support there are sections with a smooth outer surface.  7. The molecular vacuum pump according to any one of claims 1 to 4, characterized in that the holes for communicating with the evacuated cavity are located in the middle part of the housing, and the holes for communicating with the atmosphere are located on the end of the housing from the end of the rotor adapted to communicate with the electric motor, while in the case there are additional openings designed to communicate with the atmosphere, which are located at its other end, at the same distance from the openings located in the middle part, then the main holes intended for communication with the atmosphere, and on the outer surface of the rotor between the holes located in the middle part and the additional holes are grooves in the form of multiple threads, essentially similar to the main grooves, but having the opposite direction of the thread, forming an additional flow a part with a pumping direction opposite to that of the main flow part.  8. The molecular vacuum pump according to any one of claims 1 to 4, 7, characterized in that it contains a magnetic support to maintain the axial clearance between the housing and the rotor located at the other end of the rotor and containing a ring and a disk or cylinder made of magnetically hard material located coaxially, however, the disk or cylinder is rigidly connected to the shaft, and the ring to the rotor.  9. The molecular vacuum pump according to any one of claims 1 to 4, 7, characterized in that on the inner surface of the housing there are grooves in the form of multi-thread, located along the length of the main and additional flowing parts and made similar to grooves on the outer surface of the rotor, the thread direction on the housing of the corresponding flow part is opposite to the thread direction on the rotor.

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