MONITORING THE PERFORMANCE OF A CRYOPUMP

Abstract

A method of monitoring the performance of a cryopump, the circuitry for monitoring the performance and the cryopump are disclosed. The method comprises: following completion of a regeneration cycle controlling said cryopump to perform a predetermined test routine for testing a performance of said cryopump under predetermined conditions; monitoring said cryopump during said predetermined test routine to collect data indicative of said performance of said cryopump; storing data collected during said monitoring.

Claims

1. A method of monitoring the performance of a cryopump, said method comprising: following completion of a regeneration cycle controlling said cryopump to perform a predetermined test routine for testing a performance of said cryopump under predetermined conditions; monitoring said cryopump during said predetermined test routine to collect data indicative of said performance of said cryopump; storing said data indicative of said performance collected during said monitoring.

2. The method according to claim 1, said method controlling said cryopump to perform said predetermined test routine periodically after at least a subset of said regeneration cycles.

3. The method according to claim 1, comprising a further step of determining said performance of said pump from said collected data.

4. The method according to claim 3, wherein said step of determining said performance of said pump comprises comparing data obtained from a current test routine with data obtained from previous test routines.

5. The method according to claim 1, said method comprising a further step of outputting data indicative of said pump performance.

6. The method according to claim 5, wherein said step of outputting said data comprises receiving a request for said data and outputting said data in response to said request.

7. The method according to claim 1, wherein said predetermined test routine comprises determining a level of cooling provided by said cryopump at a predetermined motor speed.

8. A method according to any preceding claim, wherein said step of controlling said cryopump to perform a predetermined test routine comprises: controlling a variable speed motor controlling a flow of refrigerant through a refrigerating system of said cryopump to operate at a predetermined speed; setting a first predetermined temperature for a first stage of a refrigerator and a second predetermined temperature for a second stage of said refrigerator; and controlling heaters associated with said first and second stages of said refrigerator such that said first and second predetermined temperatures are maintained; and said step of determining the performance of said cryopump comprises determining power applied to said heaters maintaining said first and second predetermined temperatures.

9. (canceled)

10. A control and diagnostic circuitry for a cryopump, said control circuitry being configured to determine when a regeneration cycle has completed and to control said cryopump following completion of said regeneration cycle to perform a predetermined test routine for testing a performance of said cryopump under predetermined conditions; and said diagnostic circuitry is configured to: monitor said performance of said cryopump during said predetermined test routine; and store data indicative of said performance obtained from said monitoring.

11. The control and diagnostic circuitry according to claim 10, said control circuitry being configured to control said cryopump to perform said predetermined test routine periodically after at least a subset of said regeneration cycles.

12. The control and diagnostic circuitry according to claim 10, said diagnostic circuitry being configured to determine a performance of said pump from said collected data.

13. The control and diagnostic circuitry according to claim 12, wherein said diagnostic circuitry is configured to determine said performance of said pump by comparing data obtained from a current test routine with data obtained from previous test routines.

14. The control and diagnostic circuitry according to claim 10, said diagnostic circuitry being configured to output data indicative of said pump performance.

15. The control and diagnostic circuitry according to claim 14, said diagnostic circuitry being configured to output said data in response to receiving a request for said data.

16. The control and diagnostic circuitry according to claim 10, wherein said predetermined test routine comprises determining a level of cooling provided by said cryopump at a predetermined motor speed.

17. The control and diagnostic circuitry according to claim 10, wherein said control circuitry is configured to control said cryopump to perform said predetermined test routine by: controlling a variable speed motor controlling a flow of refrigerant through a refrigerating system of said cryopump to operate at a predetermined speed; setting a first predetermined temperature for a first stage of a refrigerator and a second predetermined temperature for a second stage of said refrigerator; and controlling heaters associated with said first and second stages of said refrigerators such that said first and second predetermined temperatures are maintained; and said diagnostic circuitry is configured to determine a power applied to said heaters maintaining said first and second predetermined temperatures.

18. A cryopump comprising: a refrigerator unit; a variable speed motor for controlling a flow of refrigerant through a cooling system of said cryopump; and control and diagnostic circuitry according to claim 10.

19. The cryopump according to claim 18, wherein said refrigerator unit comprises a two stage refrigerator; and said cryopump further comprises: a temperature sensor for monitoring a temperature of a first stage of said refrigerator and a temperature sensor for monitoring a temperature of a second stage of said refrigerator; and a heater for supplying heat to said first stage and a heater for supplying heat to said second stage refrigerator

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0042] Embodiments of the present invention will now be described further, with reference to the accompanying drawings, in which:

[0043] FIG. 1 shows a cryopump, and control and diagnostic circuitry according to an embodiment; and

[0044] FIG. 2 shows a flow diagram illustrating steps in a method according to an embodiment.

DETAILED DESCRIPTION

[0045] Before discussing the embodiments in any more detail, first an overview will be provided.

[0046] Embodiments provide a software-based function that is able to help determine a pump's ability to perform in a customer's operational environment. The software-based function controls the pump to perform a diagnostic test following a regeneration cycle and the information collected during the periodic diagnostic tests may be made available to service engineers to help determine the current refrigeration capacity of the pump.

[0047] In some embodiments, the cryopump comprises a variable speed motor and is configured to be operated at several operating RPM's including 72 rpm and several operating 1st and 2nd stage temperatures including 65K, 13.5K. During the test routine the pump may be controlled to operate at this fixed operating state 1st and 2nd stage temperatures typically being 65, 13.5 K and motor 72 RPM, and there will be a resulting amount of heater power applied to heaters which may be measured as a % of a maximum amount or actual watts. These power measurements are the indicator of the available refrigeration capacity and thus, the performance of the cryopump.

[0048] In some embodiments, a new pump will be tested with the test routine and the results compared with the results of subsequent test routines performed after each regeneration on the customer's tool. The results from the production test and first regeneration will be used as a baseline to monitor the pump's performance after each cooldown to keep a running trendline of performance.

[0049] The cryopump will be regenerated in the usual way and then within the cooldown phase of the set routine it is may be health checked by performing the test routine.

[0050] This procedure can be performed by a heat load calculated in Watts applied by the module to maintain predetermined temperatures such as 65K 1st stage and 13.5K 2nd stage at a set rpm of the motor/regenerators.

[0051] In some embodiments, the control circuitry will also provide an option to allow a service engineer to run a diagnostic Health check with parameters they choose by sending a special command to the module.

[0052] Regeneration is a process of warming the cryopanel surfaces with electric heaters located on the 1st and 2nd stages. N.sub.2 gas is utilized to dilute H.sub.2 gasses pumped into the charcoal of the 2nd stage on implant pumps. Then a rough/purge process is used to clean the cryopump stages at an increased temperature such as 310K and in some cases up to as high as 330K to liberate the trapped gasses out of the pressure relief valve to a gas scrubber.

[0053] The cryopump is then cooled to a set temperature, in one example 290K and evacuated to a set vacuum, for example 50 microns, then to check the effectiveness of the evacuation a rate of rise test ROR is conducted until it has passed a predetermined value of say 10 microns per minute.

[0054] After the ROR is passed the motor is started and the cryopump cools to the base temperatures which in some examples such as implant pumps is 65K/13.5K and after performing the Health Check it is ready to be utilized by the user and it is regen complete.

[0055] The cryopumps use a variable speed in some embodiments any speed between 30 and 144 rpm motor to drive the regenerators within the cylinder to utilize the helium expansion for cooling the dual stages of the refrigerator.

[0056] The revolutions per minute of the regenerators have a direct influence on the amount of cooling power or watts that the refrigerator can maintain at a set temperature.

[0057] A regeneration is described as the pump going through a set routine to warm, purge and evacuate the pump so it can be cooled down to operating temperatures the regen complete signals the customer it is ready for use.

[0058] This test routine will be run after regenerations and whenever a service engineer has access to the cryopump module and commands the test routine. Performance capabilities will be compared to previous tests to predict with the aid of service engineers the cryopump/system's performance.

[0059] Performance, dependability and safety are vital to user's of the pumps, thus being able to predict unexpected occurrences is paramount.

[0060] The health check routine is designed to look at the pump's performance over time and aid service engineers to identify possible degradation to this performance.

[0061] This allows the service engineers to visit the customer to diagnose the possible issues with the system to alleviate the issue. This may involve maintenance of the system or removal/repair of the pump/compressor or accessory prior to it disrupting the customer process and thereby reducing system tool down time.

[0062] The data collected during the test routine is stored in a data store associated with the pump and may be pulled from the data store by a service engineer or transmitted to a remote server that analyses the data in response to a signal received from the remote server requesting the data. The data may be analysed to determine both the current performance and changes in performance of the pump over time.

[0063] FIG. 1 shows a cryopump 5 according to an embodiment. Cryopump 5 is cooled by refrigeration unit 16 which is controlled by control and diagnostic circuitry 14. The refrigeration unit 16 comprises a cold finger extending into the cryopump vessel and comprises a first stage which cools the inner surface of the vessel and a frontal array (not shown) arranged across the inlet 7 and a second stage which cools the cryopanels 10 to a cooler temperature than the temperature of the first stage. The refrigerator comprises a variable speed motor 17 which drives the refrigerant, in this case helium around the refrigeration system.

[0064] There are heaters 18a and 18b associated with the first and second stage refrigerators respectively and these can be used to provide heat during regeneration and testing of the cryopump.

[0065] Cryopump 5 is used to evacuate a vacuum chamber to a high vacuum. The vacuum chamber may be used in, for example, semiconductor processing such as chip manufacture. The cryopump is a capture pump whereby gas molecules entering the cryopump are captured by condensing or adsorbing them on the cooled surfaces of the cryopump. This means that periodically the cryopump will need to be regenerated to remove the captured condensed gas.

[0066] Control circuitry 14 controls the operation of the cryopump and during regeneration of the cryopump will control the regeneration cycle. During the regeneration cycle the cryopump is isolated from the vacuum chamber generally by a gate valve and heaters 18a, 18b are used to increase the temperature of the cryopump while purge gases are input to remove any evaporated molecules. This regeneration is carried out periodically when the condensed matter in a pump rises above a value whereby the pump stops operating efficiently.

[0067] In addition to controlling the regeneration cycle, control and diagnostic circuitry 14 may be configured to perform a test routine upon completion of the regeneration cycle when the status of the cryopump is known. This test routine is used to determine the health or performance of the pump and allows degradation of the pump's performance to be monitored and failure of the pump predicted before it occurs. Unexpected failure of a pump can be very expensive particularly where the pump is used in chip manufacture and thus, predicting a failure in advance and allowing the pump to be swapped before it fails has many advantages.

[0068] The test routine is used to determine the current cooling capacity of the cryopump 5 when a motor within refrigeration unit 16 is operating at a constant speed. The motor within refrigeration unit 16 sends the refrigerant in this case helium around the refrigeration system and is generally a variable speed motor allowing the capacity of the pump and the cooling power to be changed. During the test routine the pump's speed is set to a predetermined value and the temperature sensors 12a and 12b are used to determine the temperatures of the first and second stage refrigerator and transmit the signals to circuitry 14. Circuitry 14 controls heaters 18a and 18b associated with the first and second stage refrigerator such that the temperature of the first and second stage refrigerators are maintained at certain predetermined values. These values may be selected as the normal operating temperature of the cryopump. The amount of power required by the heaters to maintain this temperature is indicative of the cooling power of the cryopump 5 and may be stored in a data store 13. A service engineer can then access this data store and determine the current performance and any changes in performance along with a rate of change in performance of the cryopump over time.

[0069] In some embodiments, there is also provided an input/output port 19 which may be used to output the current performance of the cryopump to an operator. This may be output as an indicator which may be accessed by the operator of the pump. This indicator may be a numerical value indicative of the current performance of the pump which may relate to a percentage of the optimum performance or it may simply be a colour indicative of whether the performance is currently good or not so good. In some cases it may contain an indication that a service engineer should be contacted. In other cases the data may be output via a transmitter to a remote server configured. This may occur in response to receipt of a request for the data from the remote server. The remote server may be a server configured to analyse data received from multiple pumps and to monitor their performance and any changes in performance from this data.

[0070] In some embodiments input/output port 19 may also be used to receive values input by a service engineer indicative of the motor speed and/or first and second stage temperatures to be used in the test routine. This allows these values to be updated as required. In this regard, depending on the operating conditions of the pump, different temperatures and/or motor speeds may be more appropriate for the testing of the pump.

[0071] FIG. 2 shows a flow diagram illustrating steps in a method of monitoring the performance or health of the pump according to an embodiment. Initially at step D5 it is determined whether a regeneration cycle has completed or not.

[0072] When it is determined that it has completed a test routine is initiated at step S10. In this regard, in some embodiments instead of S10 being performed after each regeneration cycle, it may only be initiated after completion of a certain number of regeneration cycles. In which case there may be an intermediate step to determine whether a counter has counted up to this certain number, the counter being incremented after each regeneration cycle has completed.

[0073] Once the test routine has been initiated then at step S20 the speed of the motor is set to a predetermined value and cooling of the cryopump starts. The temperatures of the first and second stage are set to a predetermined value in step S30. The predetermined temperatures and speed of the motor may be set values in the control/diagnostic circuitry, and/or they may be values that may be updated in response to an input by a service engineer. In step S40 the heaters are controlled to maintain the temperature of the first and second stage refrigerators at the desired predetermined temperatures. The power consumed by the heaters to maintain the temperatures is indicative of the current performance of the cryopump and thus, in step S50 the power applied to and consumed by the heaters is determined and this value is stored as an indication of the performance of the pump in step S60. This value may be stored alongside an indication of the regeneration cycle that the test routine from which the value was derived was performed after.

[0074] At S70 the current power may be compared with previous values to determine a change and/or a rate of change in the performance of the pump. This alongside the actual determined power value can be used to determine the current pump performance. In some embodiments an indicator of current performance may be output at step S80. The regeneration cycle and testing of the pump is now complete and normal operation is resumed. The diagnostic circuitry then proceeds to determine when the next regeneration cycle has started at step D15 and when it has it waits until the cycle has completed before it may again initiate the test routine at S10.

[0075] Although illustrative embodiments of the invention have been disclosed in detail herein, with reference to the accompanying drawings, it is understood that the invention is not limited to the precise embodiment and that various changes and modifications can be effected therein by one skilled in the art without departing from the scope of the invention as defined by the appended claims and their equivalents.

[0076] Although elements have been shown or described as separate embodiments above, portions of each embodiment may be combined with all or part of other embodiments described above.

[0077] Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are described as example forms of implementing the claims.