EP1377752A2 - Turbomolecular pump - Google Patents

Abstract

A turbomolecular pump (10) comprises a stator, a pump rotor, a motor (28) for driving the pump rotor and a control device (42). The control device (42) controls the motor output as to prevent the motor output from exceeding a permissible motor maximum output. Stator-side temperature sensors (32-38), which are provided for measuring the stator temperature, are arranged on the turbomolecular pump (10). The control device (42) comprises a maximum output determining device (50), that establishes the permissible motor maximum output according to the measured stator temperature. The permissible motor maximum output is thus not set to a constant value, but is always determined according to the stator temperature. This results in the power of the motor being fully exploited as long as the measured stator temperature is less than a maximum value.

Description

 Turbo molecular pump

The invention relates to a turbomolecular pump with a pump stator, a rapidly rotating pump rotor and a motor for driving the pump rotor.

In a turbomolecular pump, a gas or gas particles are compressed to produce a high vacuum by rotating blades of the pump rotor and the fixed blades of the pump stator to a multiple of the inlet pressure. The gas heating caused by the gas compression and gas friction is mainly dissipated again via the pump rotor and the pump stator. During the cooling of the pump stator can be effected by a cooling fluid leading cooling channels, the active pump rotor cooling is problematic, since the rotating pumps ^'rotor' no cooling fluid can be supplied. The pump rotor can therefore overheat under unfavorable operating conditions. If the pump rotor overheats to a maximum permissible rotor temperature, there is a risk of the pump rotor being destroyed and, as a result, of the pump stator. The turbomolecular The pump must therefore always be operated below the maximum permissible rotor temperature.

A direct measurement of the rotor temperature is only possible with great effort because of the difficult signal transmission from the fast rotating pump rotor to the stator. The turbomolecular pump therefore has a control device which limits the engine power to a predetermined constant maximum engine power, so that the pump power and the gas and rotor heating correlating therewith are also limited to a constant maximum value.

The permissible maximum motor power is calculated and / or experimentally determined by assuming the most unfavorable process conditions for pump operation, for example a thermally unfavorable gas, poor pump stator cooling, high ambient temperatures etc. The permissible maximum motor power is selected so that the pump rotor cannot exceed the maximum permissible rotor temperature even under the most unfavorable process conditions. By defining a constant maximum engine power, the engine power is limited to the predetermined maximum power even if the process conditions are more favorable than assumed for the calculation of the maximum engine power. The motor power is therefore limited to the specified maximum motor power even if the actual rotor temperature has not yet reached the maximum permissible rotor temperature. Since the extreme process conditions on which the determination of the maximum permissible maximum engine power is based are only a rare exception in practice, the output power of the turbomolecular pump is generally limited to a value far below an actually thermally permissible value. The object of the invention is therefore to create a device and a method with which the output power of a turbomolecular pump is increased.

This object is achieved with the features of claims 1 and 11 respectively.

According to the invention, a temperature sensor for measuring the stator temperature is arranged on the pump stator. Furthermore, the control device has a maximum power determination device which determines the maximum permissible motor power as a function of the measured stator temperature. The permissible maximum motor power is therefore not a constant, unchangeable value, but is determined depending on the respective stator temperature. The rotor temperature correlates strongly with the temperature of the stator-side parts of the pump, for example with the temperature of the base flange, the pump housing, the motor housing, the bearing housing, the pump stator, the motor and with the actual motor or pump power. The stator temperature therefore provides information about the rotor temperature, so that the rotor temperature can also be reliably limited to a maximum value by measuring the stator temperature and limiting the permissible maximum motor power for the respective stator temperature. By measuring the stator temperature and the conclusions that can be drawn about the rotor temperature, the permissible maximum motor power is adapted to the respective thermal situation, and is therefore usually above a constant permissible maximum motor power determined for the most unfavorable thermal circumstances. The actual motor power and thus the output power of the pump can be significantly increased in this way under normal process conditions. At the same time, the pump rotor is more reliably protected against overheating, ie exceeding the maximum permissible rotor temperature, since the rotor temperature is monitored indirectly. According to a preferred embodiment, the maximum power determination device has a rotor temperature determination device which determines the rotor temperature from the stator temperature measured by the temperature sensor. The maximum power determination device then determines the permissible maximum engine power as a function of the determined rotor temperature.

The rotor temperature determining device determines the motor rotor temperature from one or more different stator temperatures which are inserted into a polynomial whose constant coefficients were previously determined experimentally. In this way, the permissible maximum engine power can be determined quickly and with little storage space. The limitation of the maximum motor power may only intervene when a threshold temperature of the rotor is reached and limit the permissible maximum motor power, while the maximum motor power is not limited as long as the calculated rotor temperature is below the threshold temperature. The permissible maximum motor power can also be determined directly from a polynomial which is resolved according to the permissible maximum motor power and which already contains the rotor threshold temperature and / or a maximum rotor temperature in the form of coefficients.

The maximum engine power calculated on the basis of the coefficients can, if necessary, be additionally limited by other parameters.

Preferably, multiple temperature sensors are provided at various points of the stator, wherein the maximum power follow-ER- ^■ averaging means the permissible maximum motor output power in dependence on the determined gemessenen- temperatures of all temperature sensors. The temperature sensors can be attached to the housing of the turbomolecular pump, to a pump stator element part of the motor on the stator side, for example on the motor housing or on the motor winding, or in a cooling duct of the pump stator. The temperature transmitters can also be arranged at other points on the stator side of the turbomolecular pump, the temperature and temperature behavior of which allow reliable conclusions to be drawn about the temperature of the rotor. In this way, a precise conclusion on the rotor temperature and thus on the permissible maximum motor power is made possible from a large number of measured temperatures. The limitation of the engine power is therefore close to the objectively permissible maximum engine power. The determination of the rotor temperature and the permissible maximum motor power by several stator-side temperature sensors is so reliable and precise that only small safety margins have to be provided in order to avoid overheating of the rotor. In this way, the motor can be controlled with a maximum of thermally permissible power, ie the power potential of the motor and the pump can always be almost fully exhausted.

According to a preferred embodiment, the maximum power determination device has a Kehnfeld memory, in which the permissible maximum motor power for each stator temperature is stored in a map. A complex non-linear characteristic curve can also be stored in the characteristic diagram, so that a complex determination of the permissible maximum motor power through arithmetic operations can be omitted.

According to a secondary method for limiting the maximum permissible motor output of a motor in a turbomolecular pump that drives a pump rotor mounted in a pump stator, the following method steps are provided: measuring the pump stator temperature, determining a permissible maximum motor output from the measured pump stator temperature and limiting the motor output to that permissible maximum engine power determined. An exemplary embodiment of the invention is explained in more detail below with reference to the figures.

Show it:

1 shows a turbomolecular pump in longitudinal section with a plurality of temperature sensors,

FIG. 2 shows a block diagram of the regulation of the turbomolecular pump of FIG. 1.

1 shows a turbomolecular pump 10 which has a pump housing 12, one longitudinal end of which forms the suction side 14 and the other end of which forms the pressure side and has a gas outlet 16. A pump stator 18, which comprises a pump rotor 20, is arranged in the pump housing 12. The pump rotor 20 has a rotor shaft 22 which is rotatably mounted in the pump housing 12 with two radial magnetic bearings 24, 26 and an axial bearing (not shown). The rotor shaft 22 and the pump rotor 20 connected to it are driven by an electric motor 28. The electric motor 28 and the two radial magnetic bearings 24, 26 are accommodated in a common bearing motor housing 30. The pump housing

12 is cooled by a coolant flowing through a cooling channel

13 flows in the pump housing 12. The turbomolecular pump 10 • serves to generate a high vacuum and rotates at speeds of up to 100,000 rpm.

The turbomolecular pump 10 has a plurality of temperature sensors 32-38 on the stator side, ie on the side of the fixed parts. A first temperature sensor 32 is in the area of the base flange of the pump housing. 12 arranged. A second temperature sensor 34 is arranged on or in the pump stator 18. A third temperature sensor 36 is arranged on the motor 28 and measures the temperature in the area of the motor coils or the motor magnetic guide plates. A fourth temperature sensor 38 is arranged on the bearing motor housing 30. Another temperature sensor can be arranged in the course of the cooling channel 13.

The heat transferred by the gas heating of the compressed gas to the pump rotor 20 and induced by the active magnetic bearings 26 and the electric motor 28 in the pump rotor 20 is essentially dissipated by heat radiation from the pump rotor 20 to the parts on the stator side. The parts on the stator side, that is to say the pump housing 12, the pump stator 18, the bearing motor housing 30 as well as the magnetic bearings 24, 26 and the electric motor 28 are thus heated in addition to their own heating by the heat radiated onto them by the pump rotor 20. The measurement of the temperature and the temperature profile of the parts on the stator side therefore allows conclusions to be drawn about the rotor temperature.

The relationship between the actual temperature of the pump rotor 20 and the temperatures of the parts on the stator side measured by the temperature sensors 32-38 can be determined with a simple experimental setup. For this purpose, a rotor temperature sensor 40 is suitably arranged as close as possible to the pump rotor 20 on the suction side. In this way, the rotor temperature can be measured directly in the experiment, so that the relationship between the rotor temperature and the temperatures measured by the stator-side temperature sensors 32-38 can be recorded under different process conditions. A polynomial for the motor power P as a function of the rotor temperature and the stator-side temperatures can be determined from the temperatures and temperature profiles recorded by all temperature sensors 32-40: P = α ₀ +

P is the instantaneous motor power, Ti to T _n are the respectively measured temperatures of the stator-side temperature sensors 32-38 and the rotor temperature sensor 40. The coefficients α ₀ to α _n and βi to β _n are constants which are obtained by evaluating the experimentally measured pump rotor and pump location temperatures were determined. If you enter the maximum permissible rotor temperature in this polynomial instead of the measured • rotor temperature, the permissible maximum motor power P _{max is} determined with this polynomial.

There is therefore a polynomial with which the permissible maximum motor power P _max can be calculated for a set of stator temperatures Ti to T _n measured simultaneously.

In Fig. 2, the control of the pump rotor otor 28 is shown schematically. A control device 42 controls a motor driver 44, which in turn controls the coils of the electric motor 28. An engine power setpoint is output to the control device 42 via an actuating element 46. The control device 42 has a maximum output power detecting device 50 and a power limiter ^• 52nd In the maximum power determination device 50, the permissible maximum engine power P _{max is} determined from the temperature values supplied by the four temperature transmitters 32-38 according to the above formula. In the power limiter 52, the engine power setpoint value supplied by the control element 46 is limited to the determined ^• permissible maximum engine power if the power value specified by the control element 46 is greater than the determined allowable maximum engine power. In this way, the rotor temperature is limited to a maximum temperature, so that the rotor is protected from being destroyed by overheating. In addition to the cooling fluid temperature, the actual engine power, the ambient temperature and other measured variables can be used as further parameters for determining the permissible maximum engine power.

With the device described, the present rotor temperature can be inferred from a plurality of stator-side temperature sensors. In order to avoid overheating of the pump rotor to a temperature above a maximum rotor temperature, a permissible maximum motor power is determined from the determined rotor temperature, to which the motor power is limited. The permissible maximum motor power is therefore variable, so that the performance of the motor and the pump can be fully utilized and is only limited if there is a risk of overheating.

Claims

Turbomolecular pump with a stator (12, 18), a pump rotor (20), a motor (28) for driving the pump rotor (20) and a control device (42) for controlling the motor (28), the control device (42) regulating the engine power in such a way that the engine power does not exceed a permissible maximum engine power, characterized , that a temperature sensor (32-38) is arranged on the stator side for measuring the stator temperature, and that the control device (42) has a maximum power determination device (50) which determines the permissible maximum motor power as a function of the measured stator temperature. Turbomolecular pump according to claim 1, characterized in that a plurality of temperature sensors (32-38) are provided at different locations on the stator (12, 18) and the maximum power determination device (50) determines the permissible maximum engine power as a function of the measured temperatures of all Temperature sensor (32-38) determined. Turbomolecular pump according to claim 1 or 2, characterized in that the maximum power determining device (50) is assigned a rotor temperature determining device which determines the rotor temperature from the stator temperature measured by the temperature sensor (32-38) and that the maximum power determination device (50) determines the permissible maximum motor power as a function of the determined rotor temperature. 4. Turbomolecular pump according to one of claims 1-3, characterized in that the maximum power determination device (50) determines the permissible maximum engine power using a polynomial. 5. Turbomolecular pump according to one of claims 1-4, characterized in that the maxi-power determination device (50) has a map memory in which the permissible maximum engine power for each stator temperature is stored in a map. 6. turbomolecular pump according to one of claims 1-5, characterized in that the temperature transmitter (32) is provided on a pump housing (12). 7. turbomolecular pump according to one of claims 1-5, characterized in that the temperature transmitter (34) is provided on a pump stator (18). 8. Turbomolecular pump according to one of claims 1-5, characterized in that the temperature sensor (36) is provided on a stator-side part of the motor (28). 9. turbomolecular pump according to one of claims 1-5, characterized in that the motor (28) has a housing (30) and the temperature sensor (38) is provided on the motor housing. 10. Turbomolecular pump according to one of claims 1-9, characterized in that the pump housing (12) or the pump stator element (18) has a cooling channel (13) and that the temperature sensor is arranged in the course of the cooling channel (13). 11. Procedure for limiting the engine power of an engine (28) in a turbomolecular pump (10) which drives a pump rotor (20) mounted in a stator (12, 18) with the method steps Measuring the pump stator temperature, Determining a permissible maximum motor power as a function of the measured pump stator temperature, Limitation of the engine power to the determined permissible maximum engine power. 12. The method according to claim 11, characterized in that the determination of the permissible maximum engine power from the steps Calculating the pump rotor temperature from the measured pump stator temperature, Determining the permissible maximum motor power from the calculated pump rotor temperature consists.