CN215419840U - Vacuum pump motor with cantilever-mounted rotating shaft - Google Patents

Abstract

The utility model provides a vacuum pump motor with a cantilever-mounted rotating shaft, which is provided with an outer shell, wherein one end of the outer shell is provided with an end cover, the end cover is provided with an end cover hole, a stator mounting cavity is arranged inside the outer shell, the other end of the outer shell is provided with a mounting flange, the outer circumference of the mounting flange is provided with a fixing hole, the outer end surface of the mounting flange is a positioning end surface, the outermost end of the mounting flange is provided with a mounting spigot, a stator assembly is fixedly arranged inside the stator mounting cavity, the inside of the stator assembly is of a cavity structure, a rotor is arranged in a cavity inside the stator assembly, and a rotor mounting hole is arranged in the middle of the rotor; the rotor is rotationally connected with the stator assembly, and the inside of the stator mounting cavity is filled with fillers in a potting mode. The coil in the motor can be protected from being polluted by impurities, and the loss of the magnetic performance of the coil of the motor is small. The utility model can be widely applied to the field of vacuum pumps.

Description

Vacuum pump motor with cantilever-mounted rotating shaft

Technical Field

The utility model relates to a vacuum pump motor, in particular to a vacuum pump motor with a cantilever-mounted rotating shaft.

Background

In the manufacturing process of semiconductors or display screens, gases and impurities are generated in a vacuum chamber, and a vacuum pump is driven by a motor and is responsible for pumping out the gases and the impurities. The traditional vacuum pump motor is mostly composed of a stator, a rotor and a motor shell, when the vacuum pump motor runs, an impeller inside the vacuum pump rotates under the driving of the motor, impurities generated in the manufacturing process are sucked in through a suction inlet of the vacuum pump, pass through the inside of the vacuum pump and are finally discharged through a discharge outlet, and therefore the semiconductor and display screen manufacturing chamber is in a vacuum state.

When the process impurities sucked by the rotation of the impeller of the vacuum pump pass through the vacuum pump and are discharged to the outlet, part of the process impurities can flow into the motor, and the process impurities flowing into the motor can react with high-temperature gas to damage a stator coil, so that the service life of the motor can be influenced. Therefore, the conventional motor is provided with spacers between the stator and the rotor to prevent process impurities flowing in from the pump from damaging the stator coils, and these spacers are circular-welded with thin plates made of stainless steel or the like and installed between the stator and the rotor to prevent process impurities or lubricating oil flowing in from the vacuum pump from damaging the stator coils. However, since the spacer installed between the stator and the rotor must be installed between the stator and the rotor with a slight gap left, this method may be very difficult in processing and assembling. In addition, there may be problems in that the space ring installed between the stator and the rotor causes a drop and loss of magnetic force, thereby consuming a large amount of motor power, thereby increasing operating costs, and the like.

SUMMERY OF THE UTILITY MODEL

Aiming at the technical problems of the traditional vacuum pump motor, the utility model provides the vacuum pump motor which can protect the coil in the motor from being polluted by impurities, has small loss of the magnetic performance of the coil of the motor, can be fully utilized, is simple to install with a vacuum pump, is convenient to maintain, does not need a spacer ring between a stator and a rotor, has good heat dissipation effect, good sealing effect and high reliability, and can be conveniently installed with a power shaft of the vacuum pump in a cantilever manner.

The technical scheme includes that the vacuum pump motor with the cantilever-mounted rotating shaft is provided with an outer shell, an end cover is arranged at one end of the outer shell, an end cover hole is formed in the end cover, a stator mounting cavity is formed in the outer shell, a mounting flange is arranged at the other end of the outer shell, a fixing hole is formed in the outer circumference of the mounting flange, the outer end face of the mounting flange is a positioning end face, and a mounting spigot is formed at the outermost end of the mounting flange; the stator assembly is fixedly arranged in the stator mounting cavity, the interior of the stator assembly is of a cavity structure, the stator assembly comprises a stator support and a stator coil, and the stator coil is wound and connected with the stator support; a rotor is arranged in an inner cavity of the stator component, and a rotor mounting hole is formed in the middle of the rotor; the rotor is rotationally coupled to the stator assembly.

Preferably, the interior of the stator mounting cavity is potted with an interior filler, the stator assembly being located in the interior filler; the internal filler is epoxy resin.

Preferably, the outer wall of the outer shell is provided with a cooling water channel, the cooling water channel is distributed on the outer wall of the outer shell in a multi-circle spiral distribution shape, two ends of the cooling water channel are respectively provided with a cooling water inlet and a cooling water outlet, the cooling water inlet and the cooling water outlet respectively leak out of the outer wall of the outer shell, and the cooling water inlet and the cooling water outlet are communicated and hermetically connected with the cooling water channel.

Preferably, the cooling water inlet, the cooling water outlet and the cooling water channel are formed in one step during casting and machining of the outer shell.

Preferably, the sectional shape of the cooling water passage is a square or a circle.

Preferably, the clearance between the rotor and the inner cavity structure of the stator assembly is 0.6mm-1.5 mm.

Preferably, one side of the outer surface of the outer shell, which is close to the mounting flange, is provided with a middle annular groove, and one side of the outer surface of the outer shell, which is close to the end cover, is provided with an end annular groove.

Preferably, the inner side of the end cover is fixedly provided with a conical bulge.

Preferably, the outer surface of the outer housing is provided with an overheat protection means.

Preferably, a vacuum pump is fixedly arranged on the outer side of the outer shell, the rotor mounting hole is connected with the vacuum pump shaft in a matched mode, a locking screw is arranged on the outer side of the vacuum pump shaft, and the locking screw is fixedly connected with the outer end face of the rotor.

The utility model has the advantages that because the inner filling material is encapsulated in the stator mounting cavity, the stator assembly is positioned in the inner filling material and can not be exposed outside, thus, when in work, the impurities of the vacuum pump flowing in the stator assembly of the motor can be prevented from entering the inner part of the stator assembly; the internal filler 7 is generally made of epoxy resin, and the epoxy resin has good chemical resistance and thermal conductivity, so that the reliability and the performance of the motor in long-time operation can be further improved.

Because the material of shell body is aluminium metal material, the heat conductivity is better, can prevent inside the shell body that outside air got into the motor.

And because the outer wall of the outer shell is provided with the cooling water channel which is distributed on the outer wall of the outer shell in a multi-turn spiral distribution shape, various refrigerants can be conveyed in the cooling water channel, heat generated in the running process of the motor can be taken away actively, the long-time reliable running of the motor at normal temperature is ensured, and the efficiency and the reliability of the motor are improved.

Drawings

FIG. 1 is an isometric three-dimensional schematic view of the present invention;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a bottom view of FIG. 1;

FIG. 4 is a right side view of FIG. 1;

FIG. 5 is a left side view of FIG. 1;

FIG. 6 is a top view of FIG. 1;

FIG. 7 is a cross-sectional view of FIG. 4;

FIG. 8 is a cross-sectional view with the rotor removed;

figure 9 is a schematic view after installation in cooperation with a vacuum pump.

The symbols in the drawings illustrate that:

1. an outer housing; 101. an inner cavity; 102. an end cap; 103. an end cap aperture; 104. positioning the end face; 105. a fixing hole; 106. installing a spigot; 107. a middle annular groove; 108. an end annular groove; 109. a stator mounting cavity; 2. installing a flange; 3. a gap; 4. a stator coil; 5. a cooling water passage; 501. a cooling water inlet; 502. a cooling water outlet; 6. a rotor; 601. a rotor mounting hole; 7. an internal filler; 8. a stator support; 9. a vacuum pump; 901. a vacuum pump shaft; 902. locking the screw; 10. a stator assembly; 11. an elastic pad; 13. a conical boss.

Detailed Description

The present invention will be further described with reference to the following examples.

Fig. 1-9 show an embodiment of a vacuum pump motor installed on a rotating shaft cantilever according to the present invention, which is seen in the drawings, and includes an outer casing 1, an end cover 102 is disposed at one end of the outer casing 1, an end cover hole 103 is disposed on the end cover 102, a stator installation cavity 109 is disposed inside the outer casing 1, an installation flange 2 is disposed at the other end of the outer casing 1, a fixing hole 105 is disposed on an outer circumference of the installation flange 2, an outer end face of the installation flange 2 is a positioning end face 104, and an installation seam allowance 106 is disposed at an outermost end of the installation flange 2; the stator assembly 10 is fixedly arranged in the stator mounting cavity 109, the interior of the stator assembly 10 is of a cavity structure, the stator assembly 10 comprises a stator support 8 and a stator coil 4, and the stator coil 4 is wound and connected with the stator support 8; a rotor 6 is arranged in an inner cavity of the stator assembly 10, and a rotor mounting hole 601 is formed in the middle of the rotor 6; the rotor 6 is rotationally coupled to a stator assembly 10.

In the technical solution of this embodiment, the gap between the outer surface of the rotor 6 and the inner surface of the inner cavity of the stator assembly 10 is 0.6mm to 1.5mm, so as to ensure smooth operation and ensure the most suitable magnetic force distribution of the stator coil.

According to the requirement of the motor operation precision, the gap between the outer surface of the rotor 6 and the inner surface of the inner cavity of the stator assembly 10 can be designed and processed into 0.6mm-1.0mm, the gap structure can realize the normal rotation of the rotor, and can ensure the application of the magnetic force of the stator coil to the maximum extent, the magnetic loss is small, and the motor is very suitable for the occasions where the high-precision motor operates.

The stator mounting cavity 109 is internally filled with the internal filler 7, the stator assembly 10 is positioned in the internal filler 7, the internal filler 7 is epoxy resin, the internal filler 7 is filled in the stator mounting cavity 109, and the stator assembly 10 is positioned in the internal filler 7 and cannot be exposed outside, so that when the vacuum pump motor works, the impurities of the vacuum pump flowing into the stator assembly 10 of the motor can be prevented from entering the stator assembly 10; the internal filler 7 is generally made of epoxy resin, and the epoxy resin has good chemical resistance and thermal conductivity, so that the reliability and the performance of the motor in long-time operation can be further improved.

As can be seen in fig. 7-9, a gap 3 is provided between the outer end surface of the mounting spigot 106 and the outer surface of the inner filler 7 encapsulated inside the stator mounting cavity 109, which can ensure both the stability of the sizing process and the reliability of the mounting of the motor and the vacuum pump.

In this embodiment, the inboard of end cover 102 is fixed and is equipped with toper bellying 13, and toper bellying 13 is protruding to inside, can guarantee like this that the epoxy glue of bottom has the solidification volume that thickness is thicker when the glueing, guarantees the fastness of solidification and inside radiating reliability, and the bottom can be better the absorption with give off the heat that the motor produced when moving, improve the life-span of motor. Meanwhile, the end cover hole 103 in the conical protruding part 13 can be used for conveniently observing the condition inside the motor, and the operation can be facilitated when the rotor inside needs to be manually braked. The conical bulge part 13 has a relatively thick wall thickness, so that an electric appliance connector can be reliably installed, a wiring reliably enters the motor, electric connection of various coils is realized, the electric appliance connector adopts a watertight connector with good sealing performance, moisture can be further prevented from entering the motor, and the reliability of the motor is improved. The conical protruding portion 13 can also be used for fixing an internal tool during glue application, and an inner hole of the internal tool is also a conical hole and is in positioning fit with the conical protruding portion 13, so that the internal glue application process is convenient to operate.

As can be seen from fig. 7 and 8, the cooling water channel 5 is disposed on the outer wall of the outer casing 1, the cooling water channel 5 is distributed on the outer wall of the outer casing 1 in a multi-turn spiral distribution shape, the two ends of the cooling water channel 5 are respectively provided with the cooling water inlet 501 and the cooling water outlet 502, the cooling water inlet 501 and the cooling water outlet 502 respectively leak on the outer wall of the outer casing 1, the cooling water inlet 501 and the cooling water outlet 502 are connected with the cooling water channel 5 in a through sealing manner, the cooling water inlet 501, the cooling water outlet 502 and the cooling water channel 5 are formed once when the outer casing 1 is cast and manufactured, compared with the conventional structure that the cooling water channel is manufactured into a single part and then placed in a mold by casting, the cooling water channel 5 formed once is naturally formed in the inner part of the outer casing 1, so that the heat dissipation performance is better, the cross-sectional shape of the cooling water channel 5 of the embodiment is square, guarantee like this that cooling water channel 5's flow is bigger, and heat radiating area is bigger, further improves the radiating effect, also can set cooling water channel 5's cross sectional shape to circular, according to different radiating needs, nimble design, circular shape generally is fit for miniature vacuum pump motor and uses. During operation, various refrigerants are conveyed in the cooling water channel 5, heat generated in the operation process of the motor can be taken away actively, long-time reliable operation of the motor at normal temperature is guaranteed, and efficiency and reliability of the motor are improved.

In this embodiment, as can be seen from fig. 8, a middle annular groove 107 is disposed on one side of the outer surface of the outer housing 1 close to the mounting flange 2, and an end annular groove 108 is disposed on one side of the outer surface of the outer housing 1 close to the end cover 102, because the stator coil of the motor is located at the middle position of the motor, a large amount of generated heat is concentrated at the middle position of the motor, the middle cooling water channel 5 can well take away the heat, but the middle cooling water channel 5 is difficult to be arranged at two ends of the motor, therefore, the middle annular groove 107 and the end annular groove 108 are respectively disposed at two ends of the motor, and such a groove design reduces the local wall thickness of the housing of the motor, so that the heat generated at two ends of the motor can be easily dissipated, the temperature uniformity of the outer housing 1 of the motor is ensured, and the performance and reliability of the motor are further improved. The middle annular groove 107 also provides space for mounting the motor and provides a large operating space for mounting and dismounting the screws.

When the motor is used, the vacuum pump 9 is fixedly arranged on the outer side of the outer shell 1, the rotor mounting hole 601 is connected with the vacuum pump shaft 901 in a matched mode, the locking screw 902 is arranged on the outer side of the vacuum pump shaft 901, the locking screw 902 is fixedly connected with the outer end face of the rotor 6, the elastic gasket 11 is arranged between the locking screw 902 and the outer end face of the rotor 6, when the motor runs, the rotor 6 and the vacuum pump shaft 901 are different in deformation size due to different heat expansion coefficients of the rotor 6 and the vacuum pump shaft 901, and displacement difference generated by relative sliding of the rotor 6 and the vacuum pump shaft 901 can be eliminated due to the existence of the elastic gasket 11, so that the size and shape of the rotor are further guaranteed not to expand due to heat, the outer circle diameter of the rotor 6 is further influenced, the stable appearance size is achieved, and the overall performance of the motor can be further improved. The elastic washer 11 may also be a deformable support component such as a butterfly washer, and the purpose is to realize a small displacement sliding when the rotor 6 and the vacuum pump shaft 901 expand with heat and contract with cold, and to protect the whole mechanism from large deformation.

In this embodiment, the outer surface of shell body 1 is equipped with overheat protection device, and overheat protection device can be temperature switch, including bimetallic strip temperature switch etc. when the main objective was that the shell temperature is overheated, disconnection control circuit, protective apparatus can not damage the motor because of too high temperature.

Various thermistors and the like can be arranged on the outer surface or inside the motor, and the thermistor can also detect the temperature and be connected with a control system to realize the thermal protection of the motor.

The motor in the embodiment can also be connected with the frequency converter, and the frequency converter is electrically connected with the rotating shaft cantilever-mounted vacuum pump motor, so that the requirement of motor automatic control is further met. Other control technologies can be selected to be electrically connected with the motor, so that the purpose of controlling the motor to operate is achieved.

The material of shell body 1 is aluminium metal material, and the heat conductivity is better, can prevent inside the shell body 1 of outside air admission motor.

Further, in order to prevent external air from flowing into the inside of the case, the conventional motor is installed at one side of the case using an airtight terminal, and in order to prevent air from flowing in from a gap of an electric terminal installed at one side of the case, airtightness is generally maintained by a spacer provided inside the case, but in the present invention, the case plays a role of preventing external air from flowing in while the airtight terminal is installed to prevent the inflow of the internal of the case.

The utility model provides the vacuum pump motor which can protect the coil in the motor from being polluted by impurities, has small loss of the magnetic performance of the coil of the motor, can be fully utilized, is simple to install with a vacuum pump and convenient to maintain, does not need a space ring between a stator and a rotor, has good heat dissipation effect, good sealing effect and high reliability, can conveniently realize cantilever installation with a power shaft of the vacuum pump, and is more convenient to maintain.

However, the above description is only exemplary of the present invention, and the scope of the present invention should not be limited thereby, and the replacement of the equivalent components or the equivalent changes and modifications made according to the protection scope of the present invention should be covered by the claims of the present invention.

Claims (10)

1. The utility model provides a rotation axis cantilever installation vacuum pump motor which characterized by: the stator mounting structure is provided with an outer shell, one end of the outer shell is provided with an end cover, the end cover is provided with an end cover hole, a stator mounting cavity is arranged inside the outer shell, the other end of the outer shell is provided with a mounting flange, the outer circumference of the mounting flange is provided with a fixing hole, the outer end face of the mounting flange is a positioning end face, and the outermost end of the mounting flange is provided with a mounting spigot; the stator assembly is fixedly arranged in the stator mounting cavity, the interior of the stator assembly is of a cavity structure, the stator assembly comprises a stator support and a stator coil, and the stator coil is wound and connected with the stator support; a rotor is arranged in an inner cavity of the stator component, and a rotor mounting hole is formed in the middle of the rotor; the rotor is rotationally coupled to the stator assembly.

2. A rotary shaft cantilever-mounted vacuum pump motor according to claim 1, wherein: the interior of the stator mounting cavity is filled with an inner filler in a potting mode, and the stator assembly is located in the inner filler; the internal filler is epoxy resin.

3. A rotary shaft cantilever-mounted vacuum pump motor according to claim 1, wherein: the outer wall of the outer shell is provided with a cooling water channel, the cooling water channel is distributed on the outer wall of the outer shell in a multi-circle spiral distribution shape, two ends of the cooling water channel are respectively provided with a cooling water inlet and a cooling water outlet, the cooling water inlet and the cooling water outlet are respectively leaked out of the outer wall of the outer shell, and the cooling water inlet and the cooling water outlet are connected with the cooling water channel in a penetrating and sealing manner.

4. A rotary shaft cantilever-mounted vacuum pump motor according to claim 3, wherein: the cooling water inlet, the cooling water outlet and the cooling water channel are formed in one step during casting and machining of the outer shell.

5. A rotary shaft cantilever-mounted vacuum pump motor according to claim 3, wherein: the cross section of the cooling water channel is square or round.

6. A rotary shaft cantilever-mounted vacuum pump motor according to claim 1, wherein: the clearance between the rotor and the inner cavity structure of the stator component is 0.6mm-1.5 mm.

7. A rotary shaft cantilever-mounted vacuum pump motor according to any one of claims 1 to 6, wherein: one side of the outer surface of the outer shell, which is close to the mounting flange, is provided with a middle annular groove, and one side of the outer surface of the outer shell, which is close to the end cover, is provided with an end annular groove.

8. A rotary shaft cantilever-mounted vacuum pump motor according to any one of claims 1 to 6, wherein: the inner side of the end cover is fixedly provided with a conical bulge.

9. A rotary shaft cantilever-mounted vacuum pump motor according to any one of claims 1 to 6, wherein: and an overheating protection device is arranged on the outer surface of the outer shell.

10. A rotary shaft cantilever-mounted vacuum pump motor according to any one of claims 1 to 6, wherein: the outer side of the outer shell is fixedly provided with a vacuum pump, the rotor mounting hole is connected with a vacuum pump shaft in a matched mode, the outer side of the vacuum pump shaft is provided with a locking screw, and the locking screw is fixedly connected with the outer end face of the rotor.

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