Vacuum systems often comprise a main vacuum pump which is driven by a drive motor and associated with various sensors, valves and other peripheral devices. The main vacuum pump may also be associated with a vacuum roughing pump and a secondary pump for specific gases such as water vapor. Cryopumps and turbomolecular pumps, for example, generally include temperature and pressure sensors and purge and roughing valves. A turbomolecular pump may also be associated with a cryopump such as a single stage cryogenic water pump. The cryogenic water pump would also have associated sensors and control valves.
Cryogenic vacuum pumps, or cryopumps, currently available generally follow a common design concept. A low temperature array, usually operating in the range of 4 to 25 K, is the primary pumping surface. This surface is surrounded by a higher temperature radiation shield, usually operated in the temperature range of 60 to 130 K, which provides radiation shielding to the lower temperature array. The radiation shield generally comprises a housing which is closed except at a frontal array positioned between the primary pumping surface and a work chamber to be evacuated.
In operation, high boiling point gases such as water vapor are condensed on the frontal array. Lower boiling point gases pass through that array and into the volume within the radiation shield and condense on the lower temperature array. A surface coated with an adsorbent such as charcoal or a molecular sieve operating at or below the temperature of the colder array may also be provided in this volume to remove the very low boiling point gases such as hydrogen. With the gases thus condensed and/or adsorbed onto the pumping surfaces, only a vacuum remains in the work chamber.
In systems cooled by closed cycle coolers, the cooler is typically a two-stage refrigerator having a cold finger which extends through the rear or side of the radiation shield. High pressure helium refrigerant is generally delivered to the cryocooler through high pressure lines from a compressor assembly. Electrical power to a displacer drive motor in the cooler is usually also delivered through the compressor.
The cold end of the second, coldest stage of the cryocooler is at the tip of the cold finger. The primary pumping surface, or cryopanel, is connected to a heat sink at the coldest end of the second stage of the cold finger. This cryopanel may be a simple metal plate or cup or an array of metal baffles arranged around and connected to the second-stage heat sink. This second-stage cryopanel also supports the low temperature adsorbent.
The radiation shield is connected to a heat sink, or heat station, at the coldest end of the first stage of the refrigerator. The shield surrounds the second-stage cryopanel in such a way as to protect it from radiant heat. The frontal array is cooled by the first-stage heat sink through the side shield or, as disclosed in U.S. Pat. No. 4,356,701, through thermal struts.
After several days or weeks of use, the gases which have condensed onto the cryopanels, and in particular the gases which are adsorbed, begin to saturate the cryopump. A regeneration procedure must then be followed to warm the cryopump and thus release the gases and remove the gases from the system. As the gases evaporate, the pressure in the cryopump increases, and the gases are exhausted through a relief valve. During regeneration, the cryopump is often purged with warm nitrogen gas. The nitrogen gas hastens warming of the cryopanels and also serves to flush water and other vapors from the cryopump. By directing the nitrogen into the system close to the second-stage array, the nitrogen gas which flows outward to the exhaust port minimizes the movement of water vapor from the first array back to the second-stage array. Nitrogen is the usual purge gas because it is inert and is available free of water vapor. It is usually delivered from a nitrogen storage bottle through a fluid line and a purge valve coupled to the cryopump.
After the cryopump is purged, it must be rough pumped to produce a vacuum about the cryopumping surfaces and cold finger to reduce heat transfer by gas conduction and thus enable the cryocooler to cool to normal operating temperatures. The rough pump is generally a mechanical pump coupled through a fluid line to a roughing valve mounted to the cryopump.
Control of the regeneration process is facilitated by temperature gauges coupled to the cold finger heat stations. Thermocouple pressure gauges have also been used with cryopumps but have generally not been recommended because of a potential of igniting gases released in the cryopump by a spark from the current-carrying thermocouple. The temperature and/or pressure sensors mounted to the pump are coupled through electrical leads to temperature and/or pressure indicators.
Although regeneration may be controlled by manually turning the cryocooler off and on and manually controlling the purge and roughing valves, a separate regeneration controller is used in more sophisticated systems. Leads from the controller are coupled to each of the sensors, the cryocooler motor and the valves to be actuated.
Another form of vacuum pump used in high vacuum systems, such as semiconductor processing systems, is the turbomolecular pump. A turbomolecular pump comprises a high speed turbine which drives the gas molecules. Since the turbomolecular pump operates most efficiently in the molecular flow region, the gas molecules which are driven through the pump are removed by a roughing vacuum pump which maintains a vacuum in the order of 10−3 torr at the foreline, or exhaust, of the turbomolecular pump.
Because the gas as being pumped by the turbomolecular pump may be extremely corrosive or hazardous in other ways, it is often diluted by a purge gas in the foreline region of the pump. To that end, a purge valve is coupled to the pump to introduce purge gas from an inert gas supply. The purge gas is typically introduced into the motor/bearing region.
During shutdown of the pump, gas is typically introduced about the turbine blades through a separate vent valve. The vent gas prevents back streaming of hydrocarbons from the bearing lubricants in the foreline and assists in slowing of the pump by introducing a fluid drag.
To allow the turbomolecular pump to operate more effectively, some systems use a heater blanket about the housing to warm the blades and housing during operation and to thus evaporate any condensed gases. During continued operation, cooling water is circulated through the pump to prevent overheating of the bearings. Typical systems include a sensor for sensing bearing temperature in order to provide a warning with overheating.
A rack mounted control box is generally used to convert power from a standard electrical outlet to that required by the pump drive motor. The motor driving the turbine is typically a DC brushless motor driven through a speed control feedback loop or an AC synchronous motor. More sophisticated controllers may be connected to the various valves of the system to open and close those valves according to some user programmable sequence. Leads from the controller are coupled to the pump drive motor, the temperature sensor and each valve to be actuated.
In accordance with one aspect of the present invention, a vacuum system comprises a vacuum pump with a drive motor, purge and roughing valves and an electronic control module as an integral assembly. The purge valve introduces purge gas into the vacuum pump and the roughing valve opens a foreline of the vacuum pump to a roughing pump. The electronic control module has a programmed processor for controlling the vacuum pump, drive motor, purge valve and roughing valve. The electronic control processor is user programmable for establishing specific control sequences in controlling the vacuum pump drive motor, purge valve and roughing valve.
Preferably, the electronic processor is mounted in a housing of a module which is adapted to be removably coupled to the vacuum. A control connector on the module is adapted to couple the electronics to a vacuum pump motor and to the valves. A power connector is adapted to connect the electronics, to a power supply. The electronic module may store system parameters such as temperature, pressure, regeneration times and the like. It preferably includes a nonvolatile random access memory so that the parameters are retained even with loss of power or removal of the module from the pump.
Preferably, the electronic module has the control connectors and power connectors at opposite ends thereof, and it is adapted to slide into a housing fixed to the vacuum. The module is locked in place such that it cannot be removed so long as a power lead is coupled to the connector. A keyboard and display may be pivotally mounted at the end of the fixed housing opposite to the end in which the module is inserted and thus opposite to the power connector. Preferably, the display is reversible to allow for both upright and inverted orientations of the cryopump.
One vacuum system embodying the present invention comprises a motor driven turbomolecular pump and a roughing valve for opening a foreline of the turbomolecular pump to a roughing pump. A purge valve introduces purge gas into the turbomolecular pump to dilute gas being pumped. An electronic control module has a programmed processor for controlling the turbomolecular pump drive motor, purge valve and roughing valve. The processor is user programmable for establishing specific control sequences. The module is removable from the integral assembly and is connected to the drive motor and valves through a common connector assembly.
The preferred system further comprises a sensor for sensing that purge gas is being introduced into the turbomolecular pump. The sensor may sense load on the turbomolecular pump by sensing current through the pump motor or it may sense foreline pressure. During operation, the purge gas may be tested by sensing system response as the purge valve is closed and opened.
The system may comprise a heater for heating the turbomolecular pump and a sensor for sensing temperature of the turbomolecular pump. The electronic control module responds to the temperature sensor and drives the heater to control the temperature of the turbomolecular pump.
The electronic control module may control shutdown of the vacuum system by turning off power to the drive motor and opening the vent valve. Only subsequently is the roughing valve closed. By thus closing the roughing valve only after the vent valve has been opened, there can be no back streaming of gases through the turbomolecular pump as the pump slows down. By introducing the vent gas into a midsection of the rotor, potential damage to the bearings with the prompt pressure change is avoided. A delay of a few seconds between opening of the vent valve and closing of the roughing valve is preferred.
After a power failure, the system will typically open the vent valve to prevent back streaming once the rotor speed has dropped below a threshold value. With return of power, the electronic control only continues normal drive to the turbomolecular pump drive motor if the rotor remains above that threshold speed. Otherwise a start-up procedure must be initiated.
The system may further include a pressure sensor, and the electronic control may control the speed of the drive motor to the driven turbomolecular pump in response to the sensed pressure. The sensed pressure may be the total pressure sensed by a thermocouple pressure gauge or an ionization gauge, or in some cases it may more advantageously be a partial pressure as can be obtained through a residual gas analyzer.
An accelerometer may be included to provide vibrational information.
Individual and local electronic control of each vacuum pump has many advantages over strictly central and remote control. Although the present system has the advantage of being open to control and monitoring from a remote central station, control of any pump is not dependent on that central station. Therefore, but for a power outage, it is much less likely that all pumps in a system will be down simultaneously. The local storage of data such as calibration data and data histories are readily retained in the local memory without requiring any access to the central station. Thus, for example, in servicing a vacuum by replacing a module, the service person need not input any new data into the central computer because all necessary information is retained and set at the pump itself. Also, in servicing a pump, it is much more convenient to the service person to have full control of the pump when he is at the pump itself rather than having to seek control through a remote computer. The local full control of the vacuum facilitates enhancements to individual pumps because there is no burden on the central computer. As a result, many procedural improvements which provide faster, more thorough regeneration are more likely to be implemented. The removable module greatly facilitates servicing of the unit, and the battery-backed memory allows such servicing without loss of data. The module also facilitates upgrading of any individual pump.
The foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
A description of preferred embodiments of the invention follows.
As illustrated in
A first-stage heat station 50 is mounted at the cold end of the first stage 52 of the refrigerator. Similarly, heat station 54 is mounted to the cold end of the second stage 56. Suitable temperature sensor elements 58 and 60 are mounted to the rear of the heat stations 50 and 54.
The primary pumping surface is a cryopanel array 62 mounted to the heat sink 54. This array comprises a plurality of disks as disclosed in U.S. Pat. No. 4,555,907. Low temperature adsorbent is mounted to protected surfaces of the array 62 to adsorb noncondensible gases.
A cup-shaped radiation shield 64 is mounted to the first stage heat station 50. The second stage of the cold finger extends through an opening in that radiation shield. This radiation shield 64 surrounds the primary cryopanel array to the rear and sides to minimize heating of the primary cryopanel array by radiation. The temperature of the radiation shield may range from as low as 40 K at the heat sink 50 to as high as 130 K adjacent to the opening 68 to an evacuated chamber.
A frontal cryopanel array 70 serves as both a radiation shield for the primary cryopanel array and as a cryopumping surface for higher boiling temperature gases such as water vapor. This panel comprises a circular array of concentric louvers and chevrons 72 joined by a spoke-like plate 74. The configuration of this cryopanel 70 need not be confined to circular, concentric components; but it should be so arranged as to act as a radiant heat shield and a higher temperature cryopumping panel while providing a path for lower boiling temperature gases to the primary cryopanel.
As illustrated in
Less conventional in the cryopump is a heater assembly 69 illustrated in FIG. 2. The heater assembly includes a tube which hermetically seals electric heating units. The heating units heat the first stage through a heater mount 71 and a second stage through a heater mount 73.
For safety, the heater has several levels of interlocks and control mechanisms. They are as follows: (1) The electrical wires and heating elements are hermetically sealed. This prevents any potential sparks in the vacuum vessel due to broken wires or bad connections. (2) The heating elements are made with special temperature limiting wire. This limits the maximum temperature the heaters can reach if all control is lost. (3) The heaters are proportionally controlled by feedback from the temperature sensing diodes. Thus, heat is called for only when needed. (4) When used for temperature control of the arrays or heat station, the maximum power level is held at 25%. (5) If the diode reads out of its normal range, the system assumes that it is defective, shuts off the heaters, and warns the user. (6) The heaters are switched on and off through two relays in series. One set of relays are solid state and the other are mechanical. The solid state relays are used to switch the power when in the temperature control mode. The mechanical relays are part of the safety control and switch off all power to both heaters if a measured temperature, or a diode, goes out of specification. (7) The electronics have in them a watchdog timer. This device has to be reset ten times a second. Thus, if the software program (which contains the heater control software) fails to properly recycle, the timer will not be reset. If it is not reset, it shuts off everything, and then reboots the system.
As will be discussed in greater detail below, the refrigerator motor 40, cryopanel heater assembly 69, purge valve 80 and roughing valve 84 are all controlled by the electronic module. Also, the module monitors the temperature detected by temperature sensors 58 and 60 and the pressure sensed by the TC pressure gauge 86.
The control pad 28 has a hinged cover plate 88 which, when opened, exposes a keyboard and display illustrated in FIG. 4. The control pad provides the means for programming, controlling and monitoring all cryopump functions. It includes an alphanumeric display 90 which displays up to sixteen characters. Longer messages can be accessed by the horizontal scroll display keys 92 and 94. Additional lines of messages and menu items may be displayed by the vertical scroll display keys 96 and 98. Numerical data may be input to the system by keys 100. The ENTER and CLEAR keys 102 and 104 are used to enter and clear data during programming. A MONITOR function key allows the display of sensor data and on/off status of the pump and relays. A CONTROL function key allows the operator to control various on and off functions. The RELAYS function key allows the operator to program the opening and closing of two set point relays. The REGEN function key activates a complete cryopump regeneration cycle, allows regeneration program changes and sets power failure recovery parameters. The SERVICE function key causes service-type data to be displayed and allows the setting of a password and password lockout of other functions. The HELP function key provides additional information when used in conjunction with the other five keys. Further discussion of the operation of the system in response to the function keys is presented below.
In accordance with the present invention, all of the control electronics required to respond to the various sensors and control the refrigerator, heaters and valves is housed in a module 106 illustrated in
Once the module is secured within the housing 26 by screws 116 and 118, power lines may be coupled to the input connector 120 and an output connector 122. The output connector allows a number of cryopumps to be connected in a daisy chain fashion as discussed below. Due to the elongated shape of the heads of the screws 116 and 118, those screws may not be removed until the power lines have been disconnected.
Also included in the end of the module is a connector 124 for controlling external devices through relays in the module and a connector 126 for receiving inputs from an auxiliary TC pressure sensor. A connector 128 allows a remote control pad to be coupled to the system. Connectors 130 and 132 are incoming and outgoing communications ports for coupling the pump into a network. An RS232 port 133 allows access and control from a remote computer terminal, directly or through a modem.
A typical network utilizing the cryopump of the present invention is illustrated in
Operation of the system in response to the control panel is illustrated by the flowcharts of
When the cryopump is off at 194, it may be turned on by pressing the 1 button. The microprocessor then checks the status of power to the cryocooler motor. The cryopump receives separate power inputs from the compressor for the cooler motor, the heater and the electronics. If two-phase power is available, the cryopump is turned on; if not, availability of one-phase power is checked at 198. In either case, the no cryopower display 200 or 202 is provided, and operator checks are indicated through help messages at 204 and 206.
In scrolling from the “cryo on” display 190 or “cryo off” display 194 in the control function, one obtains the auxiliary TC status indications. If the gauge is on, the pressure is displayed. Again, the help message 212 indicates how the auxiliary TC may be turned on or off, or how the monitor function displays may be scrolled.
If the control function is again scrolled, the status of the cryopump TC gauge is indicated at 214 or 216. If the TC gauge is off at 216 and the 1 button is pressed, the microprocessor performs a safety check before carrying out the instruction. The TC gauge can only be turned on if the second-stage temperature is below 20 K or if the cryopump has been purged as indicated at 218 and 220. If the temperature is below 20 K, there is insufficient gas in the pump to ignite. If the cryopump has just been purged, only inert is present. If neither of those conditions exists, a potentially dangerous condition may be present and turning the gauge on is prevented at 222.
Continuing to scroll through the control function, one obtains the open/closed status of the roughing valve at 224 or 226. If the roughing valve is closed at 224, it may be opened by pressing the 1 button. However, the valve is not immediately opened if the cryopump is indicated to be on at 226. Opening the roughing valve may back stream oil from the roughing pump into the cryopump and contaminate the adsorbent. If the cryopump is on, a warning is displayed at 228, and the help message indicates that opening the valve while the cryopump is on may contaminate the cryopump. The system only allows the valve to be opened if the operator presses an additional key 2.
The next item in the control function menu is the status of the purge valve at 232 and 234. Again, if the operator attempts to open the purge valve by pressing the 1 button, the system checks whether the cryopump is on at 236. If so, opening the purge valve may swamp the pump with purge gas, and an additional warning is displayed at 238. The help message indicates that opening the valve may contaminate the cryopump but allows the operator to open the valve by pressing the 2 button.
With the next item on the menu, the on/off status of relay 1 and the manual/automatic mode status of the relay is indicated at 242, 244 and 246. The relay may be switched between the on and off positions if in the manual mode by pressing the zero and 1 buttons and may be switched between manual and automatic modes by pressing the 7 and 9 buttons as indicated by the menu messages 248 and 250. Similarly, the relay 2 status is indicated at 252, 254 and 256 in the next step of the menu.
When the screen displays the first-stage temperature under the RELAYS function, and the operator presses the enter button, the lower and upper limits are displayed at 282. As indicated by the help message 284, digits may be keyed in through the control pad to indicate a range within the possible range of 30 K to 300 K. At 282, the lower limit may be entered. If a value outside the acceptable range is entered at 286, the entry is questioned at 288, and the help message at 290 indicates that the number was out of bounds. The operator must clear and try again. If the entry is properly within the range at 292, the entry is successful when the operator presses the enter button at 294, and the display indicates that the upper limit may be programmed at 296. The help message 298 indicates that the range must be between the lower limit set by the operator and 300 K. Again, if an improper entry is made at 300, the display questions the upper limit at 302, and a help message at 304 indicates that the number is out of bounds. The number must be cleared and retried. If the value is within the proper range at 306, the newly programmed lower and upper limits are displayed at 308.
As already noted, the relays may be set to operate between lower and upper limits for one of the second-stage temperature, cryo TC pressure gauge and auxiliary TC pressure gauge in the manner described with respect to the first-stage temperature. The lower and upper limits are 10 K and 310 K for the second-stage temperature gauge, and 1 micron and 999 micron for each of the TC pressure gauges. As indicated by the help message 314, the time delay must be from zero to 99 seconds.
Operation of the system after the SERVICE button is pressed at 318 is illustrated in FIG. 12. The serial number of the cryopump is displayed at 320. Scrolling through the menu, one also obtains the number of hours that the pump has been operating at 322 and the number of hours that the pump has been operating since the last regeneration at 324.
To proceed through the remainder of the service menu, one must have a password. Thus, at 326 the system requests the password. If the proper password is keyed in at 328, the password is displayed at 330, and the operator is able to proceed. At this point, the operator may enter a new password to replace the old at 332. If the value is within an allowable range, it may be entered and displayed at 334. Otherwise, the system questions the password at 336, and the password must be cleared.
From entry of the proper password at 330, the operator may scroll to the lock mode status display at 338. The lock mode inhibits the REGEN, RELAYS and CONTROL functions of the control pad and thus subjects to the password the entire system, but for the MONITOR and the HELP functions and the limited service information presented prior to the password request. Where the lock mode is on, an operator must have access to the proper password in order to enter the full service function and turn the lock mode off before the CONTROL, REGEN or RELAYS functions can be utilized. Thus, there are two levels of protection: the service function by which the lock mode is controlled can only be entered with use of the password; the regen control and relay functions can only be entered where the lock mode has been turned off by an operator with the password. Thus the operator with the password may make the other functions available or not available to operators in general.
Three additional functions which are included within this first level of password protection are the zeroing of the auxiliary and cryopump TC pressure gauges at 340 and 342 and control of the first-stage heater during operation of the cryopump at 344. In the first-stage temperature control mode at 344, the heater prevents the temperature of the first-stage from dropping below 65 K. It has been found that, where the first-stage is allowed to become cooler than 65 K, argon may condense on the first stage during pumpdown. However, to reach full vacuum, the argon must be released from the first stage and pumped by the colder second stage. Thus, the condensation on the first stage delays pumpdown. By maintaining the temperature of the first stage above 65 K, such “argon hang-up” is avoided.
The thermocouple gauges are relatively high pressure gauges which should read zero when the vacuum is less than 10−4. Such a vacuum is assured where the second stage is at a temperature less than 20 K. Thus, at a condition where a gauge should read zero, it may be set to zero by pressing the enter button at 340 or 342. In the present system, however, these steps are generally unnecessary for the cryopump TC pressure gauge since the microprocessor is programmed to zero the TC gauge after each regeneration. After regeneration, the lowest possible pressure of the system is assured, and this is a best time to zero the gauge.
The REGEN function allows both starting and stopping of the regeneration cycle as well as programming of the cycle to be followed when regeneration is started. Operation of the system after the REGEN function key is pressed at 346 is illustrated in
Programming of the regeneration cycle may be performed by scrolling from 348 or 354 as indicated by the help messages 350 and 356. At 360, a start delay may be programmed into the system. When thus programmed, the cryopump continues to operate for the programmed time after a regeneration is initiated at 348 and 352. A delay of between zero and 99.9 hours may be programmed. At 362, a restart delay of up to 99.9 hours may be programmed into the system. Thus, the regeneration would be performed at the time indicated by the start delay of 360, but the cryopump would not be cooled down for the restart delay after completion of the regeneration sequence. This, for example, allows for starting a weekend regeneration cycle followed by a delay until restart on a Monday morning.
An extended purge time may be programmed at 364. At 366, the number of times that the pump may be repurged if it fails to rough out properly is programmed. Regeneration is aborted after this limit is reached. At 368, the base pressure to which the pump is evacuated before starting a rate of rise test is set. At 370, the rate of rise which must be obtained to pass the rate of rise test is set. At 372, the number of times that the rate of rise test is performed before regeneration is aborted is set. Use of the above parameters in a regeneration process is described in greater detail below with respect to
In the event of a power failure, the system may be set to follow a power failure sequence by entering 1 at 374. Details of the sequence are presented below with respect to
An example of the process of programming a value in the regeneration mode is illustrated in FIG. 13D. This example illustrates programming of the base pressure at 368 of
A typical regeneration cycle is illustrated in
After a 15-second wait at 402 to allow set point relays R1 and R2 to activate any external device, the purge valve 80 is opened at 404. Throughout warm-up, the display indicates at 406 the present second-stage temperature and the temperature of 310 K to be reached. A purge test is performed at 408. In the purge test, the second-stage temperature is measured and is expected to increase by 20 K during a 30-second period. If the system passes the purge test, the heaters are turned on at 410 to raise the temperature to 301 K as indicated at 412. If the system fails the purge test, the heaters are not turned on until the second-stage temperature reaches 150 K as indicated at 414. If a system fails to reach that temperature in 250 minutes as indicated at 416, regeneration is aborted, as indicated on the display at 418.
After the heaters are turned on, the system must reach 310 K within 30 minutes as indicated at 420 or the regeneration is aborted as indicated at 422. After the system has reached 310 K, the purge is extended at 414 for the length of time previously programmed into the system at 416. After the extended purge, the purge valve 80 is closed at 418, and the roughing valve 84 is opened at 420. During this time, the roughing pump draws the cryopump chamber to a vacuum at which the cryogenic refrigerator is sufficiently insulated to be able to operate at cryogenic temperatures.
A novel feature of the present system is that the heaters are kept on throughout the rough pumping process to directly heat the cryopumping arrays. The continued heating of the arrays requires a bit more cooling by the cryogenic refrigerator when it is turned on, but evaporates gas from the system and thus results in a more efficient rough pumping process.
The system waits at 422 as rough pumping continues until the base pressure programmed into the system at 424 is reached. During the wait, the rate of pressure drop is monitored in a roughout test at 426. So long as the pressure decreases at a rate of at least two percent per minute, the roughing continues. However, if the pressure drop slows to a slower rate, it is recognized that the pressure is plateauing before it reaches the base pressure, and the system is repurged. In the past, the repurge has only been initiated when the system failed to reach a base pressure within some predetermined length of time. By monitoring the rate of pressure drop, the decision can be made at an earlier time to shorten the regeneration cycle. When the system fails the roughout test at 426, the processor determines at 428 whether the system has already gone through the number of repurge cycles previously programmed at 430. If not, the purge valve is opened at 432, and the system recycles through the extended purge at 414. If the preprogrammed limit of repurge cycles has been reached, regeneration is aborted as indicated at 434. If the total roughing time has exceeded sixty minutes as indicated at 436, regeneration is also aborted.
Once the base pressure is reached with roughing, the roughing valve 84 to the roughing pump is closed at 426. A rate of rise test is then performed at 438. In the rate of rise test, the system waits fifteen seconds and measures the TC pressure and then waits thirty seconds and again measures the TC pressure. The difference in pressures must be less than that programmed for the rate of rise test at 440 or the test fails. With failure, the system determines at 442 whether the number of ROR cycles has reached that previously programmed at 444. If so, regeneration is aborted. If not, the roughing valve is again opened at 420 for further rough pumping.
Once a system has passed the ROR test, it waits at 446 an amount of time previously programmed for delay of restart at 448. If restart is to be delayed, the heaters are turned off at 450, and the purge valve is opened so that the flushed cryopump is backfilled with inert nitrogen. The system then waits for the programmed delay for restart before again opening the roughing valve at 420 and repeating the roughing sequence. Thus, regeneration is completed promptly through the ROR test even where restart is to be delayed. This gives greater opportunity to correct any problems noted in regeneration and avoids delays in restart due to extended cycling in the regeneration cycle. However, the regenerated system is not left at low pressure because the low pressure might allow air and water to enter the pump and contaminate the arrays if any leak is present. Rather, the regenerated system is held with a volume of clean nitrogen gas. Later, when the restart delay has passed, the system is again rough pumped from 420 with the full expectation of promptly passing the ROR test at 438.
When the cryopump is to be restarted after successful rough pumping, the heaters are turned off at 456, and the cryopump is turned on at 458. The system is to cool down to 20 K within 180 minutes as indicated at 462 or regeneration is aborted. Once cooled to 20 K, the cryopump TC pressure gauge is automatically zeroed at 464. As previously discussed, the system is now at its lowest pressure, and at this time the TC pressure gauge should always read zero. The cryopump TC pressure gauge is then turned off at 466 and regeneration is complete.
If at 476 it is determined that the system had already been in regeneration, it determines at 490 whether the pump was in the process of cooling down. If not, the regeneration cycle is restarted at 488. If the pump was cooling down, the system determines whether the cryopump TC gauge indicates a pressure of less than 100 microns. If not, regeneration is restarted at 488. If so, cool down is continued at 494 to complete the original regeneration cycle. After power failure, the “regen start” and “cryo restart” delays are always ignored because the time of power outage is unknown and the system errs in favor of an operational system.
Although it is often important to prevent casual operation of the system through the control pad by unauthorized personnel, it is also important that the system not be shut down because an individual having the password is not available. The present system allows for override of the password by service personnel. However, service personnel are not always immediately available, and it may be desirable to override the password through a phone communication. Thus, it is desirable to be able to provide the user with an override password which can be input on the control pad. On the other hand, one would not want the individual to thereafter have unlimited access to the cryopump control at later times, so the override password must have a limited life. To that end, the microprocessor is programmed to respond to a password which the system can determine to be valid for only the present state of the system. It stores a cryptographic algorithm from which, based on its time of operation, it can compute the valid override password. Similarly, a trusted source has access to the same algorithm. If the password is to be bypassed, the operator provides the trusted source with the operating time of the cryopump which is indicated in the service function at 322 of FIG. 12. That time is generally different for each pump in a system and is never repeated for a pump. The trusted source then computes the override password and gives the password to the operator over the telephone. When input into the system, the system confirms by computing the override password from its own algorithm and then provides the password which had previously been programmed into the system by the unavailable operator. When the unavailable operator returns, the operator would presumably code a new password into the system. The override password would no longer be usable because the operating time of the system would change.
When coupled to a computer terminal through the RS232 port, all of the functions available through the control pad may be performed through the computer terminal. Further, additional information stored in the battery-backed RAM is available for service diagnostics. Specifically, the computer terminal may have access to the specific diode calibrations for the first- and second-stage temperature sensing diodes. The electronic module may store and provide to the central computer a data history as well. In particular, the system stores the following data with respect to the first ten regenerations of the system and the most recent ten regenerations: cool down time, warm-up time, purge time, rough out time, regenerator ROR cycles, and final ROR value. The system also stores the time since the last regeneration and the total number of regenerations completed. By storing the data with respect to the first ten regenerations, service personnel are able to compare the more recent cryopump operation with that of the cryopump when it was new and possibly predict problems before they occur.
A vent valve 528 is provided to introduce gas, preferably an inert gas such as nitrogen, into the turbomolecular pump during shutdown of the system. The vented gas prevents back streaming of hydrocarbons from the pump bearings to the process chamber and also serves to more quickly bring the turbine blades to a stop. Preferably, the vent gas is introduced into a midsection of the turbine in order to balance forces on the turbine with the quick change in pressure, thus minimizing wear on the bearings.
A purge valve 530 is also coupled to an inert gas source. The purge gas is typically introduced into the motor and bearing region of the pump to prevent the motor and bearings from being affected by any corrosive gases pumped through the system and also serves to dilute any hazardous gases which are pumped through the roughing valve 524 to the roughing pump.
Also included in the system is a heating jacket 532 for heating the turbine blades and housing and thus evaporating any condensed gases.
In accordance with the present invention, the turbomolecular pump system further includes an electronics controller 534 integrally packaged with the pump and the above-described valves and heater. The electronic controller responds to an internal program, which may be user modifiable, and to various sensors to control start-up, normal operation and shutdown of the system by controlling the drive motor, the heater 532 and the valves 524, 528 and 530. The sensors may include the thermocouple sensor 526, a typical bearing temperature sensor, a sensor for sensing the temperature to which the housing is heated by heater 532, a rotational speed sensor and current sensors associated with the drive motor.
The control pad 536 has a hinged cover plate 538 which, when opened, exposes a user terminal 539 with keyboard and display illustrated in FIG. 17. The control pad provides the means for programming, controlling and monitoring all turbomolecular pump functions. It includes an alphanumeric display 540 which displays up to sixteen characters. Longer messages can be accessed by the horizontal scroll display keys 542 and 544. Additional lines of messages and menu items may be displayed by the vertical scroll display keys 546 and 548. Numerical data may be input to the system by keys 550. The ENTER and CLEAR keys 552 and 554 are used to enter and clear data during programming. A MONITOR function key allows the display of sensor data. A CONTROL function key allows the operator to control various on and off functions. The I/O function key allows the operator to program the opening and closing of two set point relays. The START-UP function key allows automatic start-up and shutdown sequences to be programmed. The SERVICE function key causes service-type data to be displayed and allows the setting of a password and password lockout of other functions. The HELP function key provides additional information when used in conjunction with the other five keys.
Access through the keyboard may be limited until a predetermined password has been input. For example, use of the keyboard and display may be limited to monitoring of system parameters, and control of the system may be prohibited without the password. Within a routine which is always protected by the password, an operator may determine whether other functions are also to be protected.
A password override may be obtained from a trusted source who has access to an override encryption algorithm. The algorithm is based on a varying parameter of the system which is available to any user. The electronic processor includes means for determining the proper override password through the same encryption algorithm. The parameter of the system may, for example, be the time of operation of the system. As a result, an operator may be allowed to override the password on select occasions without having the ability to override in the future.
In accordance with the present invention, all of the control electronics required to respond to the various sensors and control the pump drive motor, heaters and valves are housed in a module 556 illustrated in
Once the module is secured within the housing 534, power lines may be coupled to connectors 570. Also included in the end of the module is a connector 506 for controlling external devices through relays in the module. Additional connectors 572 allow a remote control pad to be coupled to the system, provide incoming and outgoing communication ports for coupling the pump into a network, and provide an RS 232 port for access and control from a remote computer terminal, directly or through a modem.
An additional PROM 590 is provided. That PROM is positioned on the cryopump side of the connector 558 so it always remains with the turbomolecular pump even with replacement of the electronics module. To minimize the data lines through the connector, the PROM 590 preferably has serial data access. To allow storage of the user configuration and historical data, the PROM 590 is also electrically erasable and writable and is preferably a conventional EEPROM. Much of the data stored in the FLASH PROM 588 is copied into the EEPROM 590. However, to allow for use of a smaller memory device 590, only a limited amount of historical data is copied into that PROM.
With the three writable memory devices, RAM 586, FLASH memory 588 and EEPROM 590, the system has the fast operating characteristics of a RAM with the secure backup of a FLASH. Also, the data may be retained in the EEPROM 590 with movement of the module; yet the more secure and dynamic operation of the FLASH on the module is obtained.
The user terminal 539 is coupled to the microprocessor 580 through an RS 922 port. An external RS 232 port is provided for communication with a host computer. An SDLC multidrop port for serial communications networking with other pumps is also included through a network controller 591. The other pumps may include turbomolecular pumps and cryopumps as illustrated in U.S. Pat. No. 4,918,930.
Sensor inputs and drive outputs are handled by signal and power digital signal processor 592 which operates under control of the microprocessor 580. The signal processor 592 has its own RAM 593 and PROM 594. Digital sensor inputs such as those from switches 595 and a digital speed sensor 596 are received through a digital input controller 597. Analog sensor inputs such as motor current sensor 598, temperature sensor 599 and pressure sensor 526 are applied through multiplexer 601 and signal conditioner 602 to an analog-to-digital converter 603. A further novel feature of the system is an accelerometer 603 for providing history and alarm signals related to system vibration. Power is supplied through a power controller 604. The controller 604 drives relay outputs 605, the heaters 532, the valves designated generally as 606, power to the gauge 526 and power to motor 608. At each occurrence when the turbomolecular pump is started, there are a number of events which may take place, including the following:
A rough vacuum in the foreline must be established or the turbomolecular pump will not be capable of reaching normal rated speed. Direct control of a roughing pump via relay is required for some applications. Actuation of the foreline roughing valve 524 is also needed. The system is capable of sensing rough vacuum pressure in the foreline from gauge 526 for appropriate decision making.
At start-up, power is delivered to the turbomolecular pump motor and the rotor accelerates toward the speed setpoint. The minimum time to accelerate to the setpoint speed, commonly referred to a “run-up time,” is determined by design. Run-up time delays are required for some applications to match pumping speed characteristics to vacuum chamber volume so that a given volume is not pumped down so quickly that gas freezes or high flow velocities result.
Heat rejection from the turbomolecular pump must be managed from start-up. Typical semiconductor applications do not use fan cooling in a clean room environment, so a water cooling system is preferred.
Pump surface temperature control is desirable for bakeout and some applications where corrosive gases can condense on the internal surfaces of a turbomolecular pump. By intermittently controlling a heater blanket 532, it is quite feasible to maintain a setpoint surface temperature for a turbomolecular pump. This feature, which is not presently found in other turbomolecular pumps offers significant advantages to many of the turbomolecular pump users in metal etch.
Purge gas flow is commonly used in corrosive pumping applications to create a positive pressure within the bearing/motor cavity and prevent migration of gases into these sensitive areas. At start-up a control valve with a properly sized orifice and filter element must be opened to initiate flow of a suitable inert gas.
Prior to starting the turbomolecular pump, the pressure condition of the foreline between the roughing valve 524 and the roughing pump is checked at 609. It is assured that the pressure sensed by gauge 526 is either below some threshold pressure or is at least decreasing at a rate which indicates that the roughing valve is operational.
Once the foreline pressure is found to be adequate, the roughing valve 524 is turned on at 610. The system then delays at 612 until some preprogrammed start delay time has elapsed. Then, the drive motor is turned on at 614. The speed is then monitored at 616 to assure that the motor reaches a programmed setpoint.
Once the pump has reached rated speed, the purge valve may be opened. At 618 it is determined whether the user has designated this as a purge gas application. If so, the purge valve is opened at 620. A check is then made at 622 to determine whether the opening of the valve has in fact introduced purge gas. If a purge gas supply is properly connected to the valve, the motor should experience an increased load when the valve is opened, and that load will be sensed as an increase in motor current. Alternatively, an increase in pressure at the foreline valve 526 may be sensed. If the load on the pump fails to increase sufficiently with opening of the purge valve, an alarm is set at 624.
The system checks at 626 whether the temperature of the pump housing is above or below a setpoint. If above, the heater may be left off. If below, the heater blanket 532 is turned on at 628. The start-up procedure is complete at 630.
Once the turbomolecular pump has obtained setpoint speed it may be desirable to vary speed in conjunction with a specified process variable. Variable speed operation will ultimately depend upon the type of motor/drive used in the turbomolecular pump. DC brushless motors offer infinite speed variation, while AC induction motors are most amenable to a single low speed value (usually about 75% of rated). Pumping speed in a turbomolecular pump is directly proportional to rotating speed. Below about 50% of rated speed, most turbomolecular pumps will begin allowing the lighter gases to back diffuse from the foreline into the process chamber.
At shutdown a number of other functions must take place with termination of power to the motor as follows.
An interstage vent valve with a properly sized orifice and filter element is opened, admitting a flow of gas to quickly decelerate the turbomolecular pump rotor. Interstage venting is used to eliminate a bearing thrust load which would result from gas admission above or below the rotor stack. Users need the capability to select a suitable time delay between initiation of the shutdown sequence and opening of the vent valve. Premature actuation of the vent valve due to power interruptions and accidental stop requests can be very time consuming and aggravating. The flow of vent gas also prevents back streaming of contaminants from the foreline as the turbomolecular pump coasts to a stop. When the vent valve is opened, any flow of purge gas is typically terminated by closing the purge valve.
The foreline vacuum valve must close and the roughing pump can be shut down if control has been included for the application. When the rotor is fully decelerated the vent valve is closed.
If turbomolecular pump bakeout has not been requested, coolant flow should remain on until a predetermined setpoint has been reached. If bakeout is required, the heater blanket should be controlled to bring the pump to the specified bakeout temperature.
A shutdown procedure is illustrated in FIG. 21. The heater blanket is turned off at 632 and the motor is turned off at 634. If the purge gas is indicated to be on at 636 the purge valve is turned off at 638. A vent delay is provided at 640 to delay opening of the vent valve 642. The delay is provided in order to allow time for recovery in the event of a power interruption or an accidental stop request.
A roughing delay is provided at 644 before the roughing valve is closed at 646. By introducing the vent gas before closing of the roughing valve, any chance of back streaming of hydrocarbon from the bearing lubricant is avoided. Once the roughing valve has been closed, the shutdown procedure is complete at 648.
There are a number of diagnostic inputs which are needed for control and also to be used in a history file within memory. The following may be monitored:
1. Foreline rough vacuum pressure.
2. Valve (rough, vent, water flow and purge) position indicators.
3. Hot spot pump temperatures (motor, bearings, surface).
4. Rotational speed.
5. Run-up time.
6. Operating hours accumulated.
7. Vibration output.
8. Operational attitude.
10. Cooling water temperature.
11. Ambient air temperature.
12. Process vacuum pressure.
13. Purge gas failure.
With the information included in a history file, insight can be gained toward diagnosing turbomolecular pump health relative to the process environment. All of the above parameters may include any combination of alarm, shutdown and/or trigger messages.
One embodiment of the invention incorporates both a turbopump 520 and a cryogenic water pump 138. Examples of cryogenic water pumps are presented in U.S. Pat. No. 5,261,244 and U.S. Pat. No. 5,483,803. As shown in
While this invention has been particularly shown and described with references to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
This application is a continuation of Ser. No. 09/454,358, filed on Dec. 3, 1999, now U.S. Pat. No. 6,461,113, which is a continuation of Ser. No. 08/517,091, filed Aug. 21, 1995, now U.S. Pat. NO. 6,022,195, which is a Continuation-in-Part of Ser. No. 08/092,692, filed Jul. 16, 1993, now U.S. Pat. No. 5,443,368, the entire teachings of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
3832084 | Maurice | Aug 1974 | A |
4354356 | Milner | Oct 1982 | A |
4361418 | Tscheppe | Nov 1982 | A |
4412851 | Laine | Nov 1983 | A |
4438632 | Lessard et al. | Mar 1984 | A |
4546613 | Eacobacci et al. | Oct 1985 | A |
4602642 | O'Hara et al. | Jul 1986 | A |
4614093 | Bachler et al. | Sep 1986 | A |
4633672 | Persem et al. | Jan 1987 | A |
4667477 | Matsuda et al. | May 1987 | A |
4679401 | Lessard et al. | Jul 1987 | A |
4688261 | Killoway et al. | Aug 1987 | A |
4709579 | Parker et al. | Dec 1987 | A |
4724677 | Foster | Feb 1988 | A |
4735084 | Fruzzetti | Apr 1988 | A |
4757689 | Bachler et al. | Jul 1988 | A |
4829774 | Wassibauer et al. | May 1989 | A |
4873833 | Pfeiffer et al. | Oct 1989 | A |
4918930 | Gaudet et al. | Apr 1990 | A |
4919599 | Reich et al. | Apr 1990 | A |
4926648 | Okumura et al. | May 1990 | A |
4953359 | Forth et al. | Sep 1990 | A |
4958499 | Haefner et al. | Sep 1990 | A |
5002464 | Lee | Mar 1991 | A |
5060263 | Bosen et al. | Oct 1991 | A |
5062271 | Okumara et al. | Nov 1991 | A |
5062771 | Satou et al. | Nov 1991 | A |
5114316 | Shimizu | May 1992 | A |
5157928 | Gaudet et al. | Oct 1992 | A |
5176004 | Gaudet | Jan 1993 | A |
5209631 | Bernhardt | May 1993 | A |
5222135 | Hardy et al. | Jun 1993 | A |
5265431 | Gaudet et al. | Nov 1993 | A |
5323465 | Avarne | Jun 1994 | A |
5343708 | Gaudet et al. | Sep 1994 | A |
5348448 | Ikemoto et al. | Sep 1994 | A |
5398543 | Fukushima et al. | Mar 1995 | A |
5443368 | Weeks et al. | Aug 1995 | A |
5517823 | Andeen et al. | May 1996 | A |
5542828 | Grenci et al. | Aug 1996 | A |
5575853 | Arami et al. | Nov 1996 | A |
5582017 | Noji et al. | Dec 1996 | A |
5678759 | Grenci et al. | Oct 1997 | A |
6022195 | Gaudet et al. | Feb 2000 | A |
Number | Date | Country |
---|---|---|
106781 | Nov 1985 | CH |
2 065 782 | Jul 1981 | GB |
2-204696 | Aug 1990 | JP |
2-204696 | Aug 1990 | JP |
2-204697 | Aug 1990 | JP |
4-164188 | Jun 1992 | JP |
Number | Date | Country | |
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20020094277 A1 | Jul 2002 | US |
Number | Date | Country | |
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Parent | 09454358 | Dec 1999 | US |
Child | 10095126 | US | |
Parent | 08517091 | Aug 1995 | US |
Child | 09454358 | US |
Number | Date | Country | |
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Parent | 08092692 | Jul 1993 | US |
Child | 08517091 | US |