The present invention relates to a method of operating a pumping system.
Vacuum processing is commonly used in the manufacture of semiconductor devices and flat panel displays to deposit thin films on to substrates, and in metallurgical processes. Pumping systems used to evacuate relatively large process chambers, such as load lock chambers, to the desired pressure generally comprise at least one booster pump connected in series with at least one backing pump.
Booster pumps typically have oil-free pumping mechanisms, as any lubricants present in the pumping mechanism could cause contamination of the clean environment in which the vacuum processing is performed. Such “dry” vacuum pumps are commonly single or multi-stage positive displacement pumps having a pumping mechanism employing inter-meshing rotors located within a stator. The rotors may have the same type of profile in each stage or the profile may change from stage to stage. The backing pumps may have either a similar pumping mechanism to the booster pumps, or a different pumping mechanism.
An asynchronous AC motor typically drives the pumping mechanism of a booster pump. Such motors must have a rating such that the pump is able to supply adequate compression of the pumped gas between the pump inlet and outlet, and such that the pumping speed resulting is sufficient for the duty required.
A proportion of the power supplied to the motor of the booster pump produces heat of compression in the exhaust gas, particularly at intermediate and high inlet pressure levels, such that the pump body and rotors can heat up. If the amount of compression and differential pressure generated is not adequately controlled, there may be a risk of overheating the booster pump, ultimately resulting in lubrication failure, excessive thermal expansion and seizure.
The standard motor for the size and pumping speed of the booster pump is thus usually selected such that it should be able to supply adequate compression in normal use at low inlet pressures but a risk of overheating remains if the pump is operated at intermediate and high inlet pressure levels without a means of protection. For driving the motor, a variable frequency drive unit may be provided between the motor and a power source for the motor. Such drive units operate by converting the AC power supplied by the power source into an AC power of desired amplitude and frequency. The power supplied to the motor is controlled by controlling the current supplied to the motor, which in turn is controlled by adjusting the frequency and/or amplitude of the voltage in the motor. The current supplied to the motor determines the amount of torque produced in the motor, and thus determines the torque available to rotate the pumping mechanism. The frequency of the power determines the speed of rotation of the pumping mechanism. By varying the frequency of the power, the booster pump can maintain a constant system pressure even under conditions where the gas load may vary substantially.
In order to prevent overloading of the booster pump, the drive unit sets a maximum value for the frequency of the power (fmax), and a maximum value for the current supplied to the motor (lmax). This current limit will conventionally be appropriate to the continuous rating of the motor, and will limit the effective torque produced by the pumping mechanism and hence the amount of differential pressure resulting, thereby limiting the amount of exhaust gas heat generated.
However, if the above control is not ideal and the booster pump operates under conditions with excessive gas heat, the pumping mechanism of the booster pump will begin to overheat, causing the rotors of the pumping mechanism to expand in a uniform manner as their temperature increases. However, the stator of the pumping mechanism will expand in a non-uniform manner. Typically the hot exhaust gas causes a strong heating effect on the exhaust side of the pump, while the continued input of cold gas at the inlet causes no such heating. As a consequence, the exhaust side of the stator heats up and expands, such that there is little loss of running clearances between the hot rotors and hot stator in this region of the pump. However, there is comparatively very little heating and expansion of the stator on the inlet side of the pump, and if rotor expansion is allowed to continue, running clearances between rotor and stator are typically lost and contact occurs, typically in a specific narrow region around the colder inlet throat of the stator. In view of this, relatively complex and expensive heat exchangers or other cooling mechanisms are often employed to reduce the risk of such clashing between rotor and stator of the pumping mechanism.
It is an aim of at least the preferred embodiment of the present invention to seek to provide a relatively simple and low cost method of operating a vacuum pump to reduce the risk of clashing between a rotor and a stator of the pumping mechanism of the vacuum pump.
In a first aspect, the present invention provides a pumping system comprising a pumping mechanism; a motor for driving the pumping mechanism; means for supplying power of a variable frequency to the motor; control means for setting maximum values for a current and frequency in the motor; and means for supplying to the control means data indicative of the temperature of gas exhaust from the pumping mechanism and a temperature of the stator of the pumping mechanism, wherein the control means is configured to use the received data to adjust at least one of said maximum values during operation of the pumping system.
By monitoring these temperatures, an indication of the clearance between a rotor and a stator of the pumping mechanism can be obtained by the control means. From this, the control means can predict the onset of contact between the rotor and the stator due to over-heating of the rotor. In order to prevent clashing between the rotor and the stator, the control means can automatically reduce the maximum value for a current in the motor. With such a reduction of the maximum current value, the variable frequency drive means automatically reduces the frequency of the power supplied to the motor, which has the effect of slowing the rotation speed of the rotor and thus reducing the differential pressure across the pumping mechanism. As the differential pressure reduces, so does the heat of compression generated in the gas exhaust from the pumping mechanism, and this in turn will reduce the temperature of the rotor, thereby reducing the risk of clashing between the rotor and the stator. This can provide greater operational reliability, especially in larger, complex booster pumps, and can enable the pumping system to be used at the highest practical efficiency with minimal, or no, thermal safety risks without the use of expensive heat exchangers or other cooling mechanisms to deal with potential thermal excursions.
As the temperature of the rotor will be dependent, to a first order, on exhaust gas temperature and elapsed operating time, the temperature of the rotor can be monitored using a signal output from a first temperature sensor arranged to monitor the temperature of gas exhaust from the pumping mechanism. The data contained in this signal can be integrated over time so that the actual rotor temperature can be determined. This determination can be further enhanced by the additional use of a booster inlet pressure measurement. A second temperature sensor can be provided for supplying a signal indicative of the temperature of a chosen part of the stator. A suitable computational logic can then be applied to these temperatures to provide an accurate estimate of the running clearance between the rotor and the chosen part of the stator.
As an alternative to using the received signals to provide an indication of the clearance between the rotor and the stator of the pumping mechanism, and/or of the temperature of the rotor, the magnitudes of the signals themselves may be used by the control means to adjust the maximum value for the current in the motor.
As contact is more likely to occur where there is the greatest temperature differential between the rotor and the stator, at least one, optionally two or more, second temperature sensors are preferably located proximate an inlet throat of the pumping mechanism. These second temperature sensors may be conveniently located on the external surface of the stator of the pumping mechanism, which can enable the position of these sensors to be easily changed as required.
The estimated running clearance can be additionally modified by a measurement of the booster pump inlet pressure, which can be used to identify the inlet pressure region across which excess heat generation is most likely. This clearance estimation can be further enhanced by monitoring the stator temperature for any sudden increase, which would result from the first onset of clearance loss and frictional local heating at that point, hence detecting the start of rotor/stator contact. Alternatively, or additionally, an additional vibration sensor mounted externally on the stator can be used to detect the onset of actual rotor/stator contact.
In one embodiment, the control means is provided by a single controller that receives the signals output from the temperature sensors, and adjusts the maximum value for the current in the motor in response thereto. In another embodiment, the control means is provided by a first controller that receives the signals output from the temperature sensors, and outputs to a second controller a command signal instructing the second controller to adjust the maximum value for the current in the motor by an amount determined by the first controller using the received signals.
In a second aspect, the present invention provides a method of controlling a pumping system comprising a pumping mechanism, a motor for driving the pumping mechanism and a variable frequency drive unit for supplying power to the motor, the method comprising the steps of setting maximum values for a current and frequency in the motor, receiving data indicative of the temperature of gas exhaust from the pumping mechanism and a temperature of the stator of the pumping mechanism, and using the received data to adjust at least one of said maximum values during operation of the pumping system.
Features described above in relation to system aspects of the invention are equally applicable to method aspects of the invention, and vice versa.
Preferred features of the present invention will now be described with reference to the accompanying drawing, in which
Whilst the illustrated pumping system includes a single booster pump and a single backing pump, any number of booster pumps may be provided depending on the pumping requirements of the enclosure. Where a plurality of booster pumps are provided, these are connected in parallel so that each booster pump can be exposed to the same operating conditions. Where a relatively high number of booster pumps are provided, two or more backing pumps may be provided in parallel. Furthermore, an additional row or rows of booster pumps similarly connected in parallel may be provided as required between the first row of booster pumps and the backing pumps.
With reference to
The backing pump 14 may have either a similar pumping mechanism to the booster pump 12, or a different pumping mechanism. For example, the backing pump 14 may be a rotary vane pump, a rotary piston pump, a Northey, or “claw”, pump, or a screw pump.
The motor 32 of the booster pump 12 may be any suitable motor for driving the pumping mechanism 30 of the booster pump 12. In the preferred embodiment, the motor 32 comprises an asynchronous AC motor. A control system for driving the motor 32 comprises a variable frequency drive unit 36 for receiving an AC power supplied by a power source 38 and converting the received AC power into a power supply for the motor 32.
The drive unit 36 comprises an inverter 40 and an inverter controller 42. As is known, the inverter 40 comprises a rectifier circuit for converting the AC power from the power source 38 to a pulsating DC power, an intermediate DC circuit for filtering the pulsating DC power to a DC power, and an inverter circuit for converting the DC power into an AC power for driving the motor 32.
The inverter controller 42 controls the operation of the inverter 40 so that the power has a desired amplitude and frequency. The inverter controller 42 adjusts the amplitude and frequency of the power in dependence on an operational state of the pumping system. When the frequency of the power output from the inverter 40 varies, the speed of rotation of the motor 32 varies in accordance with the change in frequency. The drive unit 36 is thus able to vary the speed of the booster pump 12 during the evacuation of the enclosure 10 to optimise the performance of the booster pump 12.
The inverter controller 42 sets values for two or more operational limits of the drive unit 36; in particular, the maximum frequency of the power supplied to the motor 32 (fmax), and the maximum current that can be supplied to the motor 32 (lmax). As mentioned above, the value of lmax is normally set so that it is appropriate to the continuous rating of the motor 32, that is, the power at which the motor can be operated indefinitely without reaching an overload condition. Setting a maximum to the power supplied to the motor has the effect of limiting the effective torque available to the pumping mechanism 30. This in turn will limit the resulting differential pressure across the booster pump 12, and thus limit the amount of heat generated within the booster pump 12.
The inverter controller 42 also monitors the current supplied to the motor 32. The current supplied to the motor 32 is dependent upon the values of the frequency and amplitude of the AC power supplied to the motor 32 by the drive unit 36. In the event that the current supplied to the motor 32 exceeds lmax, the inverter controller 42 controls the inverter 40 to reduce the frequency of the power supplied to the motor 32, thereby reducing both the current below lmax and the speed of the booster pump 12.
As mentioned above, the inverter controller 42 pre-sets values for lmax and fmax that are appropriate to the continuous rating of the motor 32, that is, the power at which the motor can be operated indefinitely without reaching an overload condition. In order to prevent over-heating of the rotors of the pumping mechanism 30, which could lead to clashing between the rotors and the stator of the pumping mechanism 30, the inverter controller 42 is configured to adjust the value of lmax during use of the pumping system 10. By reducing the value of lmax during operation of the booster pump 12, the inverter 40 is caused to rapidly reduce the frequency of the power supplied to the motor 32. This in turn causes the rotation speed of the rotors to decrease, thus reducing the differential pressure across the pumping mechanism 30. As the differential pressure reduces, so does the heat of compression generated in the gas exhaust from the pumping mechanism 30, and this in turn will reduce the temperature of the rotors, thereby reducing the risk of clashing between the rotors and the stator. Depending on circumstances, it may also be appropriate to reduce fmax in addition.
The arrangement further comprises at least one (two are shown in
Using the signals received from the first and second temperature sensors 44, 46, an accurate estimate of the current clearance between the rotors and the stator of the pumping mechanism 32 can be determined by the controller 43. Depending on the value of this clearance, the inverter controller 42 can be commanded by the controller 43 to reduce the value of lmax during operation of the booster pump 12 to reduce the heating of the rotors of the pumping mechanism 30 and prevent clashing between the stator and the rotors. Furthermore, depending on the value of this clearance, the controller 43 may also command the inverter controller 42 to reduce the value of fmax during operation of the booster pump 12 to reduce the heating of the rotors of the pumping mechanism 30 and prevent clashing between the stator and the rotors.
A measurement of the booster pump inlet pressure can be used to identify the inlet pressure region across which excess booster heat generation is most likely. In view of this, as shown in
The estimate of the clearance can be further modified by monitoring the signals received from the second temperature sensors 46 for any sudden increase in temperature, which would result from the first onset of clearance loss and frictional local heating at the point of contact. Alternatively, as illustrated in
In the examples illustrated in
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