JP2013539202A - Customizable derivation system with smart controller - Google Patents

Abstract

  Embodiments in the present invention provide a customizable derivation system that implements a modular architecture. The customizable derivation system includes a smart controller configured to control various compressed air and motor driven pumps in various semiconductor manufacturing processes that are sensitive to defects in the printed pattern. Has been. The smart controller is configured to automatically recognize the second pump and apply a control scheme corresponding to the second pump when switching from communication with the first pump to communication with the second pump; The pump is a compressed air pump or a motor driven pump. The switching can be due to the physical disconnection of the first pump and the physical connection of the second pump, or can be caused by software.

Description

  The present invention relates generally to liquid distributors in semiconductor manufacturing processes, and more particularly to smart controllers for controlling customizable pump operations to meet various requirements in the field of semiconductor manufacturing. It relates to a new derivation system.

  There are many applications where precise control over quantity is required and / or where precise control over the rate at which fluid is derived by the pumping device is required. In semiconductor manufacturing processes, it is important to control the amount and rate at which photochemicals such as photoresist compounds are applied to a semiconductor wafer. A semiconductor manufacturing process refers to a process used to create various integrated circuits that exist in everyday electrical and electronic devices. A semiconductor manufacturing process comprises a series of optical processing steps and chemical steps. In these steps, electronic circuits are gradually formed on a wafer made of pure semiconductor material. Coatings applied to semiconductor wafers during processing typically require some kind of flatness and / or even thickness across the surface of the wafer measured in angstroms. To do. The rate at which the processing compound is applied (ie, derived) onto the wafer must be carefully controlled to ensure that the processing liquid is applied uniformly.

In the present specification, prior art documents are not described.

  Photochemicals used in the semiconductor industry are very expensive. Therefore, it is highly desirable to ensure the use of a minimal and appropriate amount of chemical and to ensure that the chemical is not damaged by the pumping device. Unfortunately, obtaining the desired quality is extremely difficult in today's pumping systems due to a number of interrelated obstacles. For example, the pressure varies from system to system due to inflowing supply problems. Due to the dynamics and properties of the fluid, the pressure will vary from fluid to fluid (eg, high viscosity fluids require large pressures). Because these faults are interrelated, sometimes solving one of many causes can cause many other problems and / or make things worse. Furthermore, various applications have various requirements. A pump system that meets the requirements of a particular application may not be appropriate in other applications.

  In semiconductor manufacturing, by using various pumps, a plurality of chemical substances can be mixed and a mixture of chemical substances can be derived onto a wafer. For example, high-performance pumps such as the Entegris IntelliGen Mini photolithography rolling edge diaphragm pump can be used to directly mix and derive chemicals. , Inc., a registered trademark). Chemicals can vary from application to application, and various applications can have different requirements. Thus, the pump system used in deriving chemicals must take into account multiple factors such as size, cost, performance (both speed and accuracy), reliability and adaptability.

  Various embodiments in the present invention are customized based on a modular architecture and comprising a single main controller for controlling various components in a multipurpose "plug and play" type derivation system The above requirements can be solved by a possible derivation system. In the present invention, the term “customizable” means that each embodiment of the derivation system according to the present invention can be easily changed, easily modified to meet various requirements, and It means that it can be easily modified. Such changes, modifications and alterations can be made dynamically whenever such a request occurs. For example, one embodiment of a customizable derivation system according to the present invention may initially be configured with a compressed air to compressed air pump configuration. Pumps driven by compressed air (ie, compressed air pumps) are generally less expensive than motor driven pumps (ie, motor driven pumps), providing positive pressure filtration and good processing speed can do. Thus, this compressed air to compressed air pump configuration can be ideal for applications such as less important layers. The pump configuration from the compressed air type to the compressed air type can be easily changed, easily modified, or easily changed from the motor drive to the motor drive in the important layer application. Can do. In some embodiments, a single main controller is configured with the necessary intelligence. Thus, herein, a single main controller is referred to as a “smart” controller. The smart controller can automatically detect changes in the customizable derivation system and operate in response to new configurations and / or new applications.

  In some embodiments, the smart controller of the customizable derivation system according to the present invention can be configured to control multiple pumps in a semiconductor manufacturing process that is sensitive to defects in the printed pattern. The plurality of pumps can comprise at least one compressed air pump and at least one motor driven pump. The customizable derivation system can further comprise multiple lines for connecting the smart controller and the track and for connecting the smart controller and various devices. In some embodiments, the various devices can include a filter with a high frequency recognition tag, a sensor, and a pump head.

  In some embodiments, the smart controller further automatically recognizes the second pump when switching one of the plurality of lines from communicating with the first pump to communicating with the second pump. Thus, the control scheme corresponding to the second pump can be applied. Accordingly, the second pump can be accurately and appropriately controlled without requiring a stop time or, in some cases, requiring a minimum stop time.

  In some embodiments, switching may occur between motor driven pumps, between compressed air pumps, or between a compressed air pump and a motor driven pump. it can. For example, the user can remove the compressed air pump from the built-in and incorporate the motor driven type. Thereby, a certain function of the compressed air pump can be taken over. Examples of functions include chemical derivation and derivation. In some embodiments, there is no need for physical removal / connection, and switching can be done entirely by software.

  In some embodiments, the smart controller further automatically recognizes the newly connected pump when interfacing to the newly connected pump and responds to the newly connected pump. The newly connected pump can be a motor driven pump or a compressed air pump. The smart controller can include an on-board database that stores information related to multiple pumps.

  In some embodiments, the smart controller can be configured to control one or more integrated pumps. In some embodiments, the integrated pump can comprise two or more compressed air pumps physically combined with each other as a unit. Two or more compressed air pumps in the unit may operate independently of each other. In some embodiments, the smart controller can be configured to control two or more compressed air pumps in the unit independently of each other.

  In some embodiments, the customizable derivation system can comprise a set of multiple feed pumps and a set of multiple derivation pumps. In some embodiments, the smart controller can be configured to control a set of feed pumps and a set of outlet pumps. The set of feed pumps and the set of outlet pumps may comprise one or more integrated pumps.

  Embodiments using software in the present invention can be implemented by suitable computer-executable instructions that may reside on one or more non-transitory computer-readable media. As used herein, the term “computer-readable medium” encompasses all types of data storage media that can be read by a processing unit such as, for example, a processor or a controller. Examples of the computer-readable storage medium include a random access memory, a read only memory, a hard drive, a data cartridge, a floppy (registered trademark) disk, a flash memory device, and the like.

  Each embodiment according to the present invention can provide a number of advantages. For example, instead of a plurality of fixed pumps, the customizable derivation system according to the present invention can support any number of different types of pumps over time. This flexibility in mixing and adapting allows the system to be tailored for each particular application, can reduce the maintenance costs of the system, Alternatively, a technique for easily updating to a new system configuration can be provided.

  The above and other aspects of the present invention will be more clearly understood by reading the following description with reference to the accompanying drawings. However, while the following description illustrates various embodiments of the invention and numerous specific details, it will be understood that the following description is not intended to limit the invention in any way. . Without departing from the spirit of the present invention, various substitutions, modifications, additions, and reconfigurations can be made within the scope of the present disclosure. Includes all additions and reconfigurations.

  The accompanying drawings, which form a part of the specification, illustrate certain aspects of the present invention. The various features illustrated in the accompanying drawings are not necessarily shown to scale. A more complete understanding of the present invention and its advantages may be obtained by reference to the following description, taken in conjunction with the accompanying drawings. In the accompanying drawings, similar features are provided with the same reference numerals.

It is a figure which shows roughly an example of the pump (referred to as "multistage pump") having a plurality of stages. It is a perspective view which shows an example of a multistage pump. It is a perspective view which shows an example of a multistage pump. It is a perspective view which shows an example of a single stage pump. FIG. 2 schematically illustrates an exemplary embodiment of a modular architecture for a customizable derivation system. FIG. 1 schematically illustrates an exemplary embodiment of a customizable derivation system with a smart controller that controls a compressed air feed pump and a compressed air derivation pump. 1 schematically illustrates an example embodiment of a customizable derivation system with a smart controller that controls a compressed air feed pump and a motorized derivation pump. FIG. FIG. 1 schematically illustrates an exemplary embodiment of a customizable derivation system with a smart controller that controls a motorized feed pump and a motorized derivation pump. FIG. 2 schematically illustrates an exemplary embodiment of a customizable derivation system having a compressed air to compressed air pump configuration. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 illustrates pump control and sequence operation in an exemplary embodiment of a customizable derivation system. FIG. 6 schematically illustrates an exemplary embodiment of an integrated pump. FIG. 6 schematically illustrates another exemplary embodiment of an integrated pump. 1 is a perspective view from above showing an exemplary embodiment of an integrated pump. FIG. It is a disassembled perspective view which shows the compressed air type pump in one Embodiment as an illustration of an integrated pump.

  The invention, various features of the invention, and advantages of the invention will be described in detail with reference to illustrative, non-limiting embodiments illustrated in the accompanying drawings and described in detail below. The Descriptions of known programming techniques, known computer software, known computer hardware, known operating platforms and known protocols may be omitted so as not to unnecessarily obscure the details of the present invention. However, although preferred embodiments are shown, it will be understood that the detailed description and specific examples are given by way of illustration only and without limiting the invention in any way. Various substitutions, modifications, additions and rearrangements within the spirit and / or scope of the inventive concept will be apparent to those skilled in the art from this disclosure.

  FIG. 1 schematically shows an example of a multistage pump 100. The multi-stage pump 100 includes a feed stage unit 105 and a separate derivation stage unit 110. A filter 120 is disposed between the feed stage unit 105 and the derivation stage unit 110 from the viewpoint of fluid flow. Filter 120 filters impurities from the process fluid. The plurality of valves can control fluid flow through the multistage pump 100. The plurality of valves include, for example, an inlet valve 125, an isolation valve 130, a barrier valve 135, a purge valve 140, a vent valve 145, and an outlet valve 147. The various valves of the multi-stage pump 100 are opened and closed to allow or prohibit fluid flow to various parts of the multi-stage pump 100. These valves can be diaphragm valves driven by compressed air (ie, gas driven) and are opened and closed depending on whether pressure is applied or vacuum is applied.

  The derivation stage unit 110 can further include a pressure sensor 112. The pressure sensor 112 determines the fluid pressure in the derivation stage unit 110. By using the pressure determined by the pressure sensor 112, various pump speeds can be controlled as described below. Examples of pressure sensors are ceramic or polymer, piezoelectric or capacitive pressure sensors, such as those manufactured by Metallux AG, Korb, Germany. The surface of the pressure sensor 112 that contacts the process fluid may be a perfluoropolymer. The pump 100 can include an additional pressure sensor. The additional pressure sensor is, for example, a pressure sensor that determines the pressure of the fluid in the feed stage unit 105 and / or a pressure sensor for reading the pressure in the feed chamber 155.

  The feed stage unit 105 and the derivation stage unit 110 may further include a rolling diaphragm pump (or a rolling diaphragm pump) in order to pump fluid in the multistage pump 100. The feed stage pump 150 (referred to as “feed pump 150”) includes, for example, a feed chamber 155 for collecting fluid, a feed stage diaphragm 160 that moves in the feed chamber 155 to move the fluid, and a feed stage diaphragm 160. A piston 165 for driving the motor, a feed screw 170, and a step motor 175 are provided. The feed screw 170 is connected to the step motor 175 via a nut, a gear, or another mechanism for transmitting energy from the motor to the feed screw 170. In one embodiment, the feed motor rotates a nut that rotates the drive screw 170 causing the piston 165 to be driven. Similarly, the lead-out stage pump 180 (referred to as “lead-out pump 180”) includes a lead-out chamber 185, a lead-out stage diaphragm 190, a piston 192, a feed screw 195, and a lead-out motor 200. Each of the feed stage unit 105 and the derivation stage unit 110 can include various pumps, and these pumps are a pump driven by a compressed air system, a hydraulic pump, and other pumps. For example, a compressed air driven pump can be used in the feed stage, and a hydraulic pump driven by a step motor can be used in the derivation stage.

  In the example shown in FIG. 1, the multistage pump 100 uses a motor configuration between the feed pump and the outlet pump. Feed motor 175 and lead-out motor 200 can be any suitable motor. For example, the lead-out motor 200 can be a permanent-magnet synchronous motor (“PMSM”). The PMSM can be controlled by a digital signal processor (“DSP”) using Field-Oriented Control (“FOC”) or other position / velocity control scheme. In some embodiments, the smart controller in the multi-stage pump 100 is configured to control the derived motor 200 using a control schema.

  The derivation motor 200 can further comprise an encoder for a real-time field of the position of the derivation motor 200 (eg, a fine line rotational position encoder). The use of a position sensor allows for accurate and repeatable control of the position of the piston 192, which provides accurate and repeatable control over fluid movement within the lead motor 185. For example, 2000 line encoders can be used to supply 8000 pulses to the DSP, which makes an accurate measurement of the position of the derived motor 200 to determine the position of the derived motor 200, It can be controlled in units of a rotation angle of 0.045 °. In addition, the PMSM can operate at low speed with little or no vibration. The feed motor 175 can also be a PMSM or a step motor. For example, the feed motor 175 can be EAD Motor's step motor No. L1LAB-005 located in Dover, New Hampshire, USA, and the derivation motor 200 can be EAD Motor's brushless DC motor No. DA23DBBL-13E17A. Can do.

  2 and 3 are perspective views showing an example of a pump assembly for the multi-stage pump 100. FIG. The multi-stage pump 100 can include a derivation block 205. Derivation block 205 defines various fluid flow paths through multi-stage pump 100. The lead pump block 205 can be a single block of PTFE or modified PTFE or other material. Because these materials do not react with many process fluids, or because they react very little, the use of these materials minimizes the addition of hardware and allows the flow path and pump chamber to be derived blocks. It can be machined directly into 205. Accordingly, the derivation block 205 reduces the need for conduit formation by providing a fluid manifold.

  The derivation block 205 can comprise various inlets and outlets to the outside. These inlets and outlets include, for example, an inlet 210 for receiving fluid, a vent outlet 215 for venting fluid during the vent segment, and a outlet outlet 220 through which fluid is discharged during the outlet segment. Derivation block 205 does not include an external purge outlet for the purge fluid return path to the feed chamber in the example of FIG. However, in other embodiments, the fluid can be purged to the outside.

  Derivation block 205 determines the path of fluid through the feed pump, the extraction pump, and filter 120. Pump cover 225 can protect against damage to feed motor 175 and lead-out motor 200, and piston housing 227 can provide protection for piston 165 and piston 192. In this example, valve plate 230 provides a valve housing for the valve system (eg, inlet valve 125, isolation valve 130, barrier valve 135, purge valve 140, vent valve 145 in FIG. 1). The valve system can be configured to guide fluid flow to various components of the multistage pump 100. In one embodiment, each of inlet valve 125, isolation valve 130, barrier valve 135, purge valve 140, and vent valve 145 is partially integrated into valve plate 230 and applies pressure to the corresponding diaphragm. The diaphragm valve is opened and closed depending on whether the vacuum is applied or the vacuum is applied.

  The valve plate 230 includes a valve control inlet for applying pressure or vacuum to the corresponding diaphragm for each valve. For example, inlet 235 corresponds to barrier valve 135, inlet 240 corresponds to purge valve 140, inlet 245 corresponds to isolation valve 130, and inlet 250 corresponds to vent valve 145. The inlet 255 corresponds to the inlet valve 125. By selectively applying pressure or vacuum to each inlet, the corresponding valve can be opened and closed. Each valve can be opened and closed based on various sequences. The sequence can vary depending on the application. The valve plate 230 can reduce the stagnation volume of the valve, can eliminate volume fluctuations due to vacuum fluctuations, can reduce vacuum requirements, and can reduce stress on the valve diaphragm. Can be configured.

  Valve control gas and vacuum are provided to the valve plate 230 by a valve control supply line 260. The valve control supply line 260 extends from the valve control manifold (covered by the manifold cover 263 or the housing cover 225) through the outlet block 205 to the valve plate 230. A valve control gas supply inlet 265 provides pressurized gas to the valve control manifold, and a vacuum inlet 270 provides vacuum (or low pressure) to the valve control manifold. The valve control manifold can function as a three-way valve and supply pressurized gas or vacuum to the appropriate inlet of the valve plate 230 via the supply line 260 so that the corresponding valve can be controlled.

  In FIG. 3, the derivation block 205 is shown as a perspective view to illustrate the various fluid flow paths formed therein. Derivation block 205 defines various chambers and various fluid flow paths for multi-stage pump 100. Feed chamber 155 and lead-out chamber 185 can be machined directly in lead-out block 205. In addition, various fluid flow paths can be machined into the derivation block 205. One fluid flow path extends from the inlet 210 to the inlet valve. A fluid flow path 280 extends from the inlet valve to the feed chamber 155. Thereby, the path from the inlet 210 to the feed pump 150 is completed. An inlet valve 125 in the valve housing 230 controls the flow between the inlet 210 and the feed pump 150. The flow path 285 guides fluid from the feed pump 150 to the isolation valve 130 in the valve plate 230. The outlet of the isolation valve 130 is connected to the filter 120 by another fluid flow path. The fluid flows from the filter 120 to the vent valve 145 and the barrier valve 135 through a plurality of paths connected to the filter 120. The outlet of the vent valve 145 is connected to the vent outlet 215, and the outlet of the barrier valve 135 is connected to the outlet pump 180 via the fluid flow path 290. During the outlet segment, the outlet pump can output fluid to the outlet 220 via the fluid flow path 295. Alternatively, during the purge segment, the lead-out pump can output fluid to the purge valve via the fluid flow path 300. During this purge segment, fluid can return to the feed pump 150 via the fluid flow path 305. Each fluid flow path may be formed directly in a PTFE (or other material) lead block so that the lead block 205 spans the various components of the multi-stage pump 100. It can function as piping for process fluid. Thereby, the necessity of forming an additional tube can be omitted or reduced. In other cases, a tube can be inserted into the derivation block 205 to define a fluid flow path.

  FIG. 3 further shows a supply line 260 for providing pressure or vacuum to the valve plate 230. Valve actuation is controlled by a valve control manifold 302 that guides either supply pressure or vacuum to each supply line 260. Each supply line 260 may include a connecting member (an example of a connecting member is indicated by reference numeral 318) having a small orifice (ie, a restriction). The orifice in each supply line helps to mitigate the effects of sharp pressure differences between the pressure or supply of vacuum to the supply line. Thereby, a valve can be opened and closed more smoothly and more slowly.

  In addition to the configuration illustrated in FIG. 1 to FIG. 3, the configuration of the multistage pump may be a configuration from a compressed air type to a motor type, or a configuration from a compressed air type to a compressed air type. Although described in terms of a multi-stage pump, the embodiments of the present invention can also be implemented as a single stage pump. FIG. 4 is a perspective view showing an example of a pump assembly for a single stage pump 4000.

  Pump 4000 can be similar to one stage of multi-stage pump 100 described above. For example, it can be the same as the derivation stage. The pump 4000 can include a pump driven by compressed air, or a rolling diaphragm pump driven by a step motor, a brushless motor, or another motor. The pump 4000 can include a derivation block 4005. The derivation block 4005 defines various fluid flow paths through the derivation pump 4000 and at least partially forms a pump chamber. The lead-out pump block 4005 can be a single block of PTFE or modified PTFE or other material. Because these materials do not react with many process fluids, or because they react very little, the use of these materials minimizes the addition of hardware and allows the flow path and pump chamber to be derived blocks. It can be machined directly into 4005. Accordingly, the derivation block 4005 reduces the need for conduit formation by providing an integrated fluid manifold. A pressure sensor can be arranged to read the pressure in the pump chamber.

  The derivation block 4005 can comprise various inlets and outlets to the outside. These inlets and outlets include, for example, an inlet 4010 for receiving fluid, a purge / vent outlet 4015 for purge / vent fluid, and a outlet outlet 4020 from which fluid is discharged during the outlet segment. The derivation block 4005 includes an external purge outlet 4010 in the example of FIG. 4 because the pump includes only one chamber. By using a suitable coupling member such as a low profile coupling member without an O-ring, the inlet and outlet to the exterior of the derivation block 4005 can be connected to the fluid line.

  Derivation block 4005 is from the inlet to the inlet valve (eg, formed at least in part by valve plate 4030), from the inlet valve to the pump chamber, from the pump chamber to the vent / purge valve, and A fluid flow path is defined from the pump chamber to the outlet 4020. The pump cover 4025 can protect against damaging the pump, and the piston housing 4027 can provide protection for the piston. The cover / housing can be formed from polyethylene or other polymer. The valve plate 4030 provides a valve housing for the valve system (eg, inlet valve and purge / vent valve). The valve system can be configured to guide fluid flow to various components of the pump 4000. Valve plate 4030 and corresponding valves can be formed in the same manner as described above with respect to valve plate 230. The purge valve can be the same size, a smaller size, or a larger size compared to the inlet valve. However, the use of a smaller purge valve can reduce the stagnation volume returning to the chamber, as described above. Each of the inlet and purge / vent valves can be partially integrated into the valve plate 4030 and opened and closed depending on whether pressure is applied to the corresponding diaphragm or vacuum is applied. It can be set as a diaphragm valve. In some implementations, some of the valves can be located outside the derivation block 4005 or can be located in additional valve plates. As an example, a PTFE seat can be interposed between the valve plate 4030 and the lead-out block 4005, thereby forming various valve diaphragms. The valve plate 4030 includes a valve control inlet (not shown) for each valve so that pressure or vacuum can be applied to the corresponding diaphragm.

  In some embodiments, rather than a fixed number of pumps, the customizable system can support various numbers of pumps over time. The customizable derivation system uses a flexible modular architecture. Customizable derivation system embodiments can also support various types of pumps, such as compressed air pumps, motorized pumps, and optional pumps. For example, in a multi-stage pump system, the first stage pump can be driven by compressed air and the second stage pump can be driven by a motor. This flexibility in mixing and adaptation allows the system to be customized for each specific application. FIG. 5 schematically illustrates an exemplary embodiment of a modular architecture 500 for a customizable derivation system.

  As shown in FIG. 5, the various uses vary depending on the chemical used, the required quality / performance level, the cost to obtain the required quality / performance level, etc. You can have a lot of demands. For example, if the cost of the chemical is high and the final product is sensitive to defects, the system can use a motor-to-motor configuration. An example of this configuration is shown in FIG. 8, where the best possible filtration control can be performed and the number of defects can be minimized. Such a configuration from a motor type to a motor type is inherently expensive, and in some cases, a configuration from a compressed air type to a motor type can be used. It is possible to reduce the cost of the system while achieving the processing capability and ensuring the observability and controllability of the derived speed and the derived amount. An example of the configuration from the compressed air type to the motor type is shown in FIG. In some cases, a configuration from compressed air to compressed air may be desirable. That is especially the case if you are interested in the cost of the derived quantity and / or if high quality performance is not required. An example of the configuration from the compressed air type to the compressed air type is shown in FIG. In the embodiment disclosed herein, the modular architecture 500 comprises a smart controller. Smart controllers can mix and adapt compressed air and motor pumps, sometimes dynamically or on the fly. Thus, the customizable derivation system embodiments disclosed herein can achieve all levels of performance for many different applications so that they can meet different requirements in the field of semiconductor manufacturing.

  This flexible modular architecture can provide the derivation system disclosed herein and can provide many advantages. For example, the system owner can start with a configuration from compressed air to compressed air. Thereafter, the owner's requirements may change and / or after evaluation, a configuration from compressed air to compressed air may need to be upgraded. One or more compressed air pumps can be easily replaced into a motor driven pump and / or a replacement compressed air pump. The owner need not replace the entire derivation system.

  Such plug-and-play modifications to the derivation system are possible, at least in part, thanks to a multi-purpose smart controller that can automatically and dynamically control various types of pumps. Has been. For example, operation can be started or resumed by removing the first pump, incorporating the second pump, and connecting the lines. At the time of connection with the pump head of the second pump, the smart controller can automatically recognize the second pump and can apply a control scheme corresponding to the second pump. In some embodiments, switching from one pump to another can be done entirely via software without the need to physically remove and install the pump. For example, the user can assign pump C and pump D with pump A and pump B offline. Thereby, the functions of the pump C and the pump D can be taken over as a new pump A and a new pump B.

  In some embodiments, electronically readable tags or codes can be used to provide a wide variety of information to the smart controller. In some embodiments, the smart controller can be connected to various devices that are made identifiable by an electronically readable tag. Electronically readable tags may or may not be directly secured to such devices / packages, and may or may not be embedded in such devices / packages. ,it can. For example, the smart controller can be connected to the smart filter via one of the many ports of the smart controller, and information about the smart filter can be electronically readable associated with the smart filter. Tags can be provided to the smart controller. In other examples, the smart controller can be connected to a pack or package, and information about the contents of the pack or package can be displayed by an electronically readable tag associated with the pack or package. Can be provided for smart controllers. The pack can contain the chemicals required for a particular application. Other devices / packages can be connected to the smart controller in a similar manner.

  In semiconductor manufacturing, various applications often have different requirements regarding chemical layer thickness and coating area. Therefore, a wide variety of derivation amounts and derivation speeds can be requested. In meeting such requirements, pumps of different sizes are provided for different track sizes because each pump needs to be able to accommodate all the fluids required for individual derivations. These trucks and pumps require separate lines for communication. This means that each input line and each output line requires a physical wire or cable. The complexity of the wires adds further challenges to the already complex fluid connections in the derivation system.

  One approach to solving such challenges is to use input / output (I / O) interface devices that can provide serial communication between individual pump controllers and trucks. Thus, individual pump controllers for the same type of pump can communicate to various tracks via the I / O interface device. More specifically, the I / O interface device takes a signal from the front end track and communicates the signal serially to the rear end pump controller in a format understandable by the pump controller. be able to.

  The smart controller embodiments disclosed herein can provide other viable solutions. In some embodiments, the smart controller can comprise multiple connection ports for physical connection to the track and various devices. In some embodiments, the smart controller can include 24 communication ports for motorized pumps, compressed air pumps, filters, sensors, and the like. Each of these motor-type pumps, compressed air-type pumps, filters, sensors, etc. can be connected to any of the 24 communication ports, which allows the smart controller to use the on-board database. Can be recognized. The communication line between the smart controller and the device can be configurable by software. In some embodiments, each type of device can be assigned to a specific port of the smart controller.

  In some embodiments, the smart controller is a serial, parallel, or analog signal for various devices such as trucks, pumps, valves, sensors, tag readers, pump heads, and other components. Various types of interface data can be provided so that data communication can be performed. In some embodiments, the interface to the track may use a proprietary protocol or an industry standard protocol. In another example, the interface to the track is a device area, a controller area network (CAN) with an industry standard Ethernet or some other industry standard protocol. be able to. For example, the smart controller can use a transmission control protocol / Internet protocol (TCP / IP) for communication with a track. By using other interfaces of the smart controller, it is possible to communicate in one or more protocols to various devices including individual pump heads. In some embodiments, the various devices can include CAN devices. In some embodiments, the interface to the various devices can include a simple, unique interface that has been disassembled.

  In many tracks, pump I / O signals can be controlled by using Ethernet, device nets, or other similar devices. For example, a track can set (or set) several signals by sending device net instructions to the device net's parallel I / O board, which are routed through connectors and cables, A special pump interface module can be reached. This type of connection architecture requires a delicate and complex hardware configuration in addition to software programming.

  In some embodiments, the smart controller can implement a unique communication protocol for interface connection / communication to the pump. In some embodiments, the smart controller can represent a commonly used parallel I / O by implementing a track interface, which can trigger a pump or perform basic You can get the current status. In some embodiments, the pumps can be implemented as the same parallel device type, and the smart controller can be configured to directly interpret the protocol. This virtually eliminates the need for a parallel signal on the pump, track hardware board or cable, while virtually providing the same programming functionality that many tracks currently use. In the following example, the track can send the same device net command to the pump through the smart controller without the need for additional hardware. One skilled in the art will appreciate that this is only one possible example. In some embodiments, communication can be made to a smart controller or pump by using a real Entegris networking protocol.

  In some conventional derivation systems, a master controller can be connected to multiple pumps, and each pump can have a dedicated pump controller connected to the respective pump. The function of this type of dedicated pump controller can be classified into two levels. That is, it can be classified into a high level and a low level. The functions of the high level controller can include the functions necessary to operate the outlet pump. The function of the low-level controller can include a simple function such as moving the motor from point A to point B, for example. These pump controllers have a large amount of processing capacity. Unfortunately, conventional derivation systems do not utilize the processing power of such pump controllers in an efficient manner. For example, in a derivation system having a plurality of pumps such as 30 to 40, for example, there are at most three pumps operating simultaneously, and the remaining pumps are in a standby state. This inefficiency results in high costs.

  Another disadvantage of conventional derivation systems is in a fixed architecture that cannot be easily corrected. The master controller is typically programmed with a control scheme corresponding to the type of pump controller to which it is connected. Because the control scheme is specific to the type of pump, the master controller can recognize the motor-driven pump if the compressed air pump is removed and replaced with a motor-driven pump. The master controller cannot know how to connect the motor-driven pump.

  The smart controller embodiments disclosed in the present invention can obtain high level functionality from the pump controller. For this reason, the processing capacity of each pump can be accurately shared. Thereby, standby time can be reduced and the corresponding cost can be reduced. The low level function remains at the pump head. The distinction between high-level functions and low-level functions can be software configured to customize the derivation system for a particular implementation. For example, in some embodiments, the smart controller can send a simple “derived” command to the pump head, and the pump head has sufficient intelligence to allow the command to be sent. Can be executed and can report to the smart controller upon completion of the task. In another example, the smart controller can give the general command “Derivation Recipe 4” to the pump controller (at the point or local to the pump) and the derivation in this particular recipe. A pump controller configured to perform can perform the indicated task. In some embodiments, the pump head can only have a basic or basic function sufficient to drive a connected pump, and the smart controller can accomplish the task at hand, Specific instructions can be provided to the pump head.

  In some embodiments, the operation of the pump is controlled by the smart controller using information about the filter connected to the pump. In some embodiments, the filter is a removable filter disposed in the fluid flow path between the pump inlet and the pump outlet. The removable filter can implement a quick change mechanism or a quick connect mechanism for connection to the pump. In some embodiments, the smart controller is configured to receive filter information, configured to receive process fluid information such as, for example, a chemical type, and further based on the filter information and the process It is configured to access a library of operating routines (control schemes) based on fluid information, which allows you to select an operating routine for the pump and drive the pump along the selected operating routine can do. The selected operating routine may comprise a priming routine, a derivation cycle, or selected segments of derivation cycles of other routines.

  FIG. 6 schematically illustrates an exemplary embodiment of a customizable derivation system 600. The customizable derivation system 600 includes a smart controller 610 that controls a compressed air feed pump 630 located on the feed stage 601 and a compressed air derivation pump 640 located on the derivation stage 602. In this example, the smart controller 610 is communicatively connected to the track 620, to the compressed air feed pump 630, to the filter 650, and to the derivation pump 640. In this example, the electronic regulator 635 can be used to control a feed pump 630 that is driven by compressed air, and the electronic regulator 645 can be used to control the feed pump that is driven by compressed air. The pump 640 can be controlled.

  FIG. 7 schematically illustrates an exemplary embodiment of a customizable derivation system 700. The customizable derivation system 700 includes a smart controller 610 that controls a compressed air feed pump 630 located on the feed stage 601 and a motor driven derivation pump 740 located on the derivation stage 602. Similar to the above example, the smart controller 610 is communicatively connected to the track 620, to the compressed air feed pump 630, to the filter 650, and to the outlet pump 740. . In the derivation system 700, the electronic regulator 635 can be used to control the feed pump 630 driven in a compressed air manner. In this example, the smart controller 610 can be configured to control the derivation pump 640 without using an electronic regulator. In some embodiments, the customizable derivation system 700 can nevertheless comprise an electronic regulator as a standard component. Thereby, various types of pumps can be mixed with respect to the outlet pump 740. For example, if desired, among the plurality of outlet pumps 740, one or more compressed air pumps connected to an electronic regulator can be mixed.

  FIG. 8 schematically illustrates an exemplary embodiment of a customizable derivation system 800. The customizable derivation system 800 includes a smart controller 610 that controls a motor driven feed pump 830 located on the feed stage 601 and a motor driven derivation pump 740 located on the derivation stage 602. . Similar to the above example, the smart controller 610 is communicatively connected to the track 620, to the feed pump 830, to the filter 650, and to the derivation pump 740. The smart controller 610 can control the motor-driven feed pump 830 and the motor-driven derivation pump 740 in the same manner as the multistage pump 100 described above. In some embodiments, the customizable derivation system 800 can comprise an electronic regulator for the feed stage 601 and an electronic regulator for the derivation stage 602 as standard components. . Thereby, various types of pumps can be mixed for the feed pump 830 and for the outlet pump 740. For example, if desired, among the plurality of feed pumps 830 in the feed stage 601, one or a plurality of compressed air pumps connected to an electronic regulator can be mixed, and a plurality in the derivation stage 602. In the derivation pump 740, one or more compressed air pumps connected to an electronic regulator can be mixed.

  FIGS. 6-8 illustrate the flexibility and versatility of the smart controller 610. The smart controller 610 includes a compressed air feed pump 630 in the feed stage 601, a compressed air delivery pump 640 in the delivery stage 602, a motor driven delivery pump 740 in the delivery stage 602, and a motor driven delivery pump in the feed stage 601. The feed pump 830 and various filters 650 can be handled. Smart controller 610 provides a plug-and-play type interface with multiple physical interfaces (ports) to track 620 and to various devices. By using the same connection line, it is possible to communicate with various types of pumps. This reduces / simplifies wiring for a customizable derivation system.

  The smart controller can provide a unique or internal standardized communication line for communicating with various devices such as compressed air pumps, motor driven pumps, filters, and the like. When communicating with these devices, the smart controller can identify each type of device when connected, can refer to the corresponding control scheme, and can drive the device accordingly. For example, when switching from communicating with one pump to communicating with another pump, the smart controller has access to an internal or local database of information, including a control scheme for the newly connected pump. And a corresponding control scheme can be applied.

  In some embodiments, the smart controller can be connected to a filter having an electronically readable filter information tag containing filter information. Some examples of electronically readable filter information tags can implement radio frequency identification (RFID) technology. The filters can be of a detachable type and can implement a quick change mechanism or a quick connect mechanism. In some embodiments, the filter information tag can be an active or passive RFID tag, a bar code, or other optically readable code.

  High frequency recognition (RFID) generally comprises two members. That is, a reader and a tag are provided. By using radio waves, some RFID tags can be read from several meters away beyond the viewing direction of the RFID reader. In some embodiments, a suitable RFID tag range is intentionally short, which can reduce crosstalk to tag readings for adjacent pumps. As an example, in one embodiment, the range of the RFID tag is as short as about 1 inch. Other ranges are possible depending on the distance and / or configuration of the RFID reader and tag. FIG. 10 shows an example of a filter 950a having an RFID tag 952a and an example of a filter 950b having an RFID tag 952b. In some embodiments, the RFID tag can be secured directly on the filter or can be embedded in the filter. In some embodiments, the RFID tag need not be physically attached to the filter. RFID technology is known to those skilled in the art. Therefore, further explanation is omitted here.

  Examples of filter information include, but are not limited to, part number, design style, membrane type, retention standard, filter generation, filter membrane configuration, lot number, serial number, device There are flow, membrane thickness, membrane point, particle quality, filter manufacturer quality information and other information. The design style indicates the type of pump the filter is to be installed on, the volume / size of the filter, the amount of membrane material in the filter, and other information regarding the configuration of the filter. The membrane type indicates the material and / or thickness of the membrane. The retention standard indicates the particle size that can be removed particularly efficiently by the membrane. The generation of the filter indicates whether the filter is the first generation, the second generation, the third generation or another generation of the filter design. The filter membrane configuration indicates whether the filter is pleated, the type of pleats, or other information regarding the configuration of the membrane. The serial number provides the serial number of the individual filter. The lot number can specify the production lot of the filter or membrane. The device flow shows the flow rate through the filter that can be handled with good derivation. The device flow can be determined at the time of manufacturing individual filters. The membrane point provides another measure of flow rate / pressure through the filter that can be handled with good derivation. The membrane point can also be determined at the time of manufacture of the individual filter. The above examples are illustrative and are not intended to limit the information that can be included in the filter information.

  The part number contained in the filter information can include various information. For example, each letter “Aabdefgh” in the example part number format can include various portions of information. Table 1 below provides an example of information contained in the part number.

  According to the example in Table 1, the part number A2AT2RMR1 for the Impact pump filter indicates the connection mode of the filter. Entegris, Inc.), the membrane is a thin UPE, the retention standard is 10 nm, the filter is a version 2 filter, the filter is equipped with an RFID tag, The membrane is equipped with M pleats, the filters are without O-rings, one filter per box. However, the use of the part number to attach information is for illustration only, and the filter information can be attached by other techniques.

  Other suitable filters can also be connected to the smart controller for other purposes. For example, the initial version of the smart filter needs to be removed and replaced with a new version. This can be done in a simple manner by pulling out the old smart filter and inserting the replacement filter into place. A plurality of rules forming a set can be applied to the filter information. This makes it possible to determine whether the filter is appropriate. The rules for determining whether a filter is appropriate can depend on the filter information and other factors such as process fluids, environmental characteristics, required cycle times, and other factors. . For example, the rule states that if the process fluid has a certain viscosity, a filter with a specific part number or a certain part number and bubble point will be considered an appropriate filter. In this way, it can be applied. Thus, the applied rules can depend on various filter information and other information. If the filter is not an appropriate filter, a corresponding operation can be performed. Otherwise, the operation of the pump can proceed.

  Smart filters can play an important role in various semiconductor manufacturing processes that are sensitive to defects in printed patterns, such as very fine micron or submicron sizes, among others. it can. Some existing derivation systems perform filtration under negative pressure. Some existing derivation systems can observe the pressure required for filtration and can possibly maintain that pressure passively. However, it is not known that conventional derivation systems have the ability to accurately control the pressure required for filtration.

  In some embodiments disclosed in the present invention, the positive pressure of the pump head at the pump inlet can be controlled and maintained on the outlet side. Thereby, bubbles caused by defects can be reduced. In the case of a motor driven pump, this positive pressure can be controlled by motor movement and by a feedback loop to the pressure transducer. For example, to provide a positive pressure of 5 psi, the upstream electronic regulator can be set to provide 10 psi in the first stage and the downstream electronic regulator can be set to 5 psi in the second stage. Can be configured to provide This pressure differential pushes fluid through the filter to the outlet side.

  In a compressed air pump set up, a pressure transducer is placed in the fluid flow path so that the actual fluid pressure can be detected. Based on the information from the smart filter, the smart controller can deduce how much the actual filtration rate is for a particular filter, thereby controlling the filtration rate. This allows the user to set the desired filtration rate in addition to setting the downstream pressure. The upstream pressure can be adjusted to achieve the desired target velocity through the filter.

As an example, the filtration rate for a pump configuration from compressed air to compressed air can be calculated as such. That is,
-The user enters the chemical viscosity (FV) for the compressed air derivation pump.
-The user enters a desired filtration pressure setpoint (FP) for an RFID filter connected in fluid communication with the pump. In some cases, the FP can be set to 4 psi. In some cases, the FP can be set to 2 psi to 10 psi.
-The user enters the desired filtration rate (FR) for chemical filtration. The FR can be set between 0.2 cc / sec and 1 cc / sec, and in some cases can be set higher.
-The controller obtains the filter flow rate (FLR) from the RFID tag of the filter. The information provided from the RFID tag can comprise the type of filter and the current flow rate of the fluid flowing through the filter.
The controller has a resistance constant (FC) stored in the firmware.
The controller calculates the filter resistance (R) based on R = FC / FLR.
-At this point, the controller has all the information necessary to calculate the upstream pressure (UFR) based on UFR = (R * FR * FV) + FP. UFP is required to obtain the filtration rate desired by the user.
The controller sets the first stage fluid pressure for UFP and the second stage fluid pressure for FP.
-Open the isolation and barrier valves.
-Filtration takes place with a given filtration rate.
-When filtration is complete, raise the fluid pressure of the first stage from FP to UFP.
-The increased pressure signals the end of filtration.

  In a particular example, the user can request a filtration rate of 1.5 cc / sec and request a downstream pressure of 4 psi on the outlet pump for the filtration of fluids with a viscosity of 3 centipoise (cps). can do. R = 1.55 and UFR = 10.98 psi are assumed. If the pressure regulator for the feed pump is set to 10.98 psi and the pressure regulator for the derivation pump is set to 4 psi, fluid movement is caused by the pressure difference through the filter, and the pressure difference through the filter is In the example, fluid is moved from the feed side to the outlet side with a flow rate of 1.5 cc / sec through the filter. The flow rate is continued until further fluid processing is required. At this point, the diaphragm of the lead-out pump will reach the bottom and the pressure regulator for the lead-out pump can no longer maintain the set point of 4 psi. In this case, the pressure in the second stage begins to drift toward the set point of 10.98 psi. After drift begins to occur, the end of filtration is indicated and the derivation pump can end the filtration and proceed to the next step in the cycle. One possible reason for this is that the pressure transducer is located in the fluid flow path. If the pressure transducer is only located in the compressed air path, no change in fluid pressure is detected.

  FIG. 9 schematically illustrates an exemplary embodiment of a customizable derivation system 900. The customizable derivation system 900 has a configuration from a compressed air pump to a compressed air pump with respect to the feed stage 901 and the derivation stage 902. In this example, feed pump 930a and feed pump 930b are physically combined as a unit. However, each pump operates independently of each other, is controlled independently of each other by the smart controller embodiment disclosed herein (see FIG. 6), and each contains a chemical for a particular derivation application. The pair of bottles 970a and 970b are connected to be capable of fluid communication. Advantageously, this configuration can provide cost savings and high processing speeds due to simultaneous derivation. Similarly, the derivation pump 940a and the derivation pump 940b are physically combined as a unit. However, each pump operates independently of each other and is controlled independently of each other by the smart controller, leading to the corresponding filter 950a, 950b, respectively, and to the corresponding purge line, and to the derivation point. (Output) Connected to the valve so as to allow fluid communication. In some embodiments, the output valve can comprise stop / suckback valves (SSBVs). The output valve can be connected to an observation / detection device for molecular contamination carried by air and other molecules and chemicals. A control amount of fluid containing processing chemical is applied (derived) through the outlet nozzle at the outlet point and onto the wafer. The rate at which the processing chemistry is applied to the wafer must be controlled to ensure that the processing fluid is applied uniformly. The thickness of the coating over the surface of the wafer is typically measured in angstroms.

  The lead-out nozzle is generally at atmospheric pressure. Preferably, the pressure level at the outlet nozzle is left undisturbed. That is, there is no high pressure, no vacuum, and no spikes. By placing a pressure transducer in the fluid flow path in a pump configuration from compressed air to compressed air, it is possible to ensure that the inlet of the outlet pump has a positive pressure, and it is necessary to make an estimate. It is possible to ensure that the positive pressure is accurately controlled at all times. The pressure transducer is a type of sensor that can generate a signal as a function of the applied pressure. In this configuration, many suitable pressure transducers can be used. In some embodiments, the positive pressure can range from 0 to 12 psi. In some embodiments, the positive pressure can range from 2 to 10 psi.

  FIGS. 10-15 illustrate pump control and sequence operation in an exemplary embodiment of a customizable derivation system 1000. The customizable derivation system 1000 has a configuration from a compressed air pump to a compressed air pump with respect to the feed stage 901 and the derivation stage 902. In this exemplary embodiment, customizable derivation system 1000 can comprise various valves. Various valves include inlet valves, isolation valves, vent valves, barrier valves, purge valves, and output valves. These valves have the same functions as the valves described above with respect to the multistage pump 100. In this example, the electronic regulator 935 can be used to control the compressed air drive of the feed pumps 930a and 930b independently of each other, and the electronic regulator 945 can be used to control the derivation pump 940a. , 940b can be controlled independently of each other. In this exemplary embodiment, customizable derivation system 1000 further comprises a smart filter 950a having an RFID tag 952a, a smart filter 950b having an RFID tag 952b, a PCB 961, and a PCB 962. Can do. In this example, because the two pumps are physically combined as one unit, a printed circuit board (PCB) is connected to this unit and to the smart controller, thereby For each command from the smart controller, one of the two pumps can be driven, or both pumps can be driven simultaneously.

  FIG. 11 shows an example of a filling and derivation sequence 1100. In this sequence 1100, the chemical substance is sucked from the bottle 970a into the feed pump 930a. For simplification of illustration, the feed pump 930b, the lead-out pump 940b, and the members / connection lines attached to these pumps are not shown in FIGS. Feed pump 930b and lead pump 940b may have the same or similar pump control and sequence operations as described herein with reference to feed pump 930a and lead pump 940a.

  The filter 950a can include a tag 952a. In operation, a tag reader (not shown) can read filter information from the tag 952a and can send this filter information to the smart controller (see FIG. 6). The smart controller can process the filter information and can apply rules to the filter information to determine how to operate the feed pump 930a and the derivation pump 940a. For example, it is possible to determine how to control the filling pressure, observe the fluid pressure profile, and generate an alarm about deviation. In addition, the smart controller can adjust the operation of the customizable derivation system 1000 during the derivation cycle based on the filter information obtained from the tag 952a.

  The smart controller can also correct good or bad operations on the filtration characteristics by using the filter information. In operation, the smart controller can track various operational data regarding the customizable derivation system 1000. Information tracked by the smart controller can comprise all operating parameters made available to the smart controller and all information calculated by the smart controller. Some non-limiting examples of operational data include pressure, various parameters related to valve operation, motor position, motor speed, hydraulic pressure, and other parameters (eg, the pump is equipped with a temperature sensor). Temperature). By using this information, it can be determined whether the derivation is a good derivation and whether the derivation was a good derivation. This can be done after derivation or in real time during the derivation cycle.

  The operational data can be correlated to the filter information. Thereby, the effect of various filter parameters on the derived quality can be verified. In one example, the smart controller can record the lot number of the filter so that customizable derivation system 1000 operational data can be correlated to that lot. By using this information, it is possible to verify whether a particular lot of filters gives good or bad results compared to other lots of filters of the same configuration. Similarly, the serial number can be used to track operational data for individual filters, which can help determine whether an individual filter has caused bad coating. In yet another embodiment, correlating operational data to membrane points may determine that filters having the same part number and different membrane points have yielded different derivation results. it can. By recording information from tag 952a and tracking information about the derivation, the selection of the filter can be optimized and even the manufacture of the filter can be optimized.

  FIG. 12 shows an example of the filtration sequence 1200. As mentioned above, smart filters can play an important role in various semiconductor manufacturing processes. In a particular example, if the first stage fluid pressure setpoint is set to 10 psi and the second stage fluid pressure setpoint is set to 8 psi, the difference between the two setpoints. The pressure is 2 psi. This differential pressure (ΔP) pulls the fluid through the filter. The filter is of a sealed type. Thus, there is no pressure loss when fluid is pushed through the filter. Depending on the flow rate and depending on the filter resistance, the pressure in the two stages eventually reaches equilibrium at the end of filtration over time. In the prior art, when the end point of filtration occurs is not accurately known in a pump configuration from compressed air to compressed air. In some embodiments, a pressure transducer can be placed in the fluid flow path. This makes it possible to provide accurate information to the pump in a timely manner, and it is possible to proceed to the next step without having to wait unnecessarily. By using the configuration shown in FIG. 10, in one example, the fluid diaphragm eventually reaches the bottom on the outlet side, and no more fluid can penetrate into the pump. On the one hand, the bottle extractor in the feed stage continues to try to push the fluid to the outlet side. This increases the fluid pressure on the outlet side and eventually increases to 10 psi. This informs the end point of filtration. In a compressed air to compressed air pump configuration, this pressure is detected by a pressure transducer located in the fluid flow path. In this case as well, the flow velocity is controlled in cooperation with the derivation stage. In the derivation stage, the downstream pressure can be controlled and the amount of defects can be minimized. Further, detection of the end point of filtration can optimize processing speed for customizable derivation systems. This is because the system can proceed to the standby state for the next derivation cycle without having to wait for a predetermined time.

  In a mixing and adapting system, the bottle extractor can draw fluid from the bottle by using a motor pump. By applying negative pressure (via an upstream electronic regulator), fluid can be pulled from the bottle into the fluid reservoir of the first stage. The use of a motor pump can have the reason that it provides a control level of sensitivity with respect to fluid flow rate and pressure. In some embodiments, the compressed air pump can be utilized at low cost. Thus, in some embodiments, the positive pressure control scheme described above is not limited to a pump configuration from compressed air to compressed air, but a pump configuration from motor driven to motor driven, It can also be implemented in a pump configuration from a motor drive type to a compressed air type. The bottle can be pressurized and by using a feed stage, the rate at which the chemical is filled can be controlled and the end point of the filling can be determined.

  In addition to the derivation cycle, the smart controller can be configured to perform other operations. For example, when a new filter is connected to the pump, the filter should be primed so that the filter membrane is sufficiently wet prior to operation of the derivation cycle. An example of a priming routine can be as follows. Initially, fluid is introduced into the outlet chamber. The filter can be vented for a predetermined time, thereby removing air bubbles from the upstream portion of the filter. A recirculation purge segment can then be performed. An example of a recirculation purge segment 1300 is shown in FIG. Recirculation purge can remove bubbles without generating chemical waste, and in addition can be important for filter priming in an effective manner. In the subsequent purge to vent segment, the isolation valve and purge valve are opened and the barrier valve is closed. Fluid is guided from the outlet chamber through the vent. This can be done after the filtration segment, the vent segment, and the purge segment. Thereafter, the filter can be pressurized while the isolation valve is opened and the fluid in the feed stage is pressurized, and the barrier valve and the vent valve can be closed. A forward flush segment can be performed in which fluid flows through the filter to the outlet chamber and is purged through a purge valve. Again, a segment from purge to vent can be performed. The priming routine can be repeated as necessary.

  The pumps in the customizable derivation system can be primed based on the type of filter and based on the process fluid being used. Thus, while the above provides an example of a priming routine, other priming routines can be used as will be appreciated by those skilled in the art. In a proper priming routine, there can be a variety of different steps to fully wet the filter membrane. Some non-limiting examples of segment sequences that may be used in the priming routine include, but are not limited to: i) fill segment and vent segment, ii) fill segment, purge to vent segment, filtration segment, vent Segment, purge to inlet segment, iii) derivation segment, fill segment, filtration segment, and purge segment. FIG. 14 shows an example of a filling segment 1400. In the fill segment 1400, the customizable derivation system 1000 is ready for the next derivation. FIG. 15 shows an example of the vent segment 1500. In the vent segment 1500, the customizable derivation system 1000 automatically vents so that when a bubble is detected by pressure observation, the bubble can be removed, thereby allowing the gas under pressure to be removed. It is possible to prevent re-dissolution. In the priming routine, additional segments or alternative segments can be used as needed.

  As described above, in some embodiments, the customizable derivation system can comprise one or more units consisting of a plurality of pumps physically connected to each other. With the aid of the PCB, the smart controller can communicate to these pumps via a single line / port / physical interface per unit. However, due to the fact that the pumps are not physically integrated, each pump still requires a full set of tubes and components. In some embodiments, a customizable derivation system according to the present invention may comprise an integrated pump with simplified wiring / tube formation requirements.

  FIG. 16 is a schematic diagram illustrating an exemplary embodiment of an integrated pump 1600 in which two compressed air pumps are physically integrated with each other as a unit. In the integrated pump 1600, two compressed air pumps (pump 1 and pump 2) share a fluid plate 1610. The fluid plate 1610 is interposed between the front plate 1611 and the end plate 1612. In a non-limiting illustration, the fluid plate can be formed from a polymeric material, such as, for example, polytetrafluoroethylene (PTFE) or some other suitable material. In a particular illustration, the fluid plate can have a height of 101.6 mm (4 inches), a width of 101.6 mm (4 inches), and a thickness of 6.35 mm (1/4 inch). . Both sides of the fluid plate can be machined or have other shapes, which can form a dish shape, a recess shape, or a concave shape. In this example, each of the compressed air pumps includes an end plate connected to one side of the fluid plate, thereby forming a cavity or space for holding fluid therein. Can do. The diaphragms 1621 and 1622 can be driven by compressed air independently of each other, and thereby can guide the fluids 1601 and 1602 across the integrated pump 1600. The mounting plate can be interposed between the end plates. Thereby, fluid communication can be provided between the fluid space and the mounting plate. In a non-limiting illustration, the end plate can be formed from metal. Other suitable materials such as plastic can also be used. As shown in FIG. 6, when the feed pump 630 includes a plurality of integrated pumps 1600, each unit including the integrated pumps includes a single control board connected thereto. In this example, the customizable derivation system 600 can easily increase the operating capacity and the possibility of operation without having to rewire each of the feed pumps 630.

  FIG. 17 shows four compressed air pumps (pump 1 for fluid 1701, pump 2 for fluid 1702, pump 3 for fluid 1703, pump 4 for fluid 1704). FIG. 6 schematically illustrates an exemplary embodiment of an integrated pump 1700 that is physically integrated with each other as a unit. The smart controller can control these pumps via a single line / port / interface. Each pump has a fluid side and a compressed air side. These pumps share certain members such as a central plate 1710, a front plate 1711, an end plate 1712, a fluid plate 1721, and a fluid plate 1722. In some embodiments, the pump can share a mounting plate and mounting member, including a fluid mounting member and a compressed air mounting member.

  FIG. 18 is a perspective view illustrating an exemplary embodiment of an integrated pump 1800. In this example, pump 1 and pump 2 of integrated pump 1800 include fluid plate 1810, front plate 1811, end plate 1812, mounting plate 1860, fluid mounting member 1885, compressed air mounting member 1895, Share.

  FIG. 19 is an exploded perspective view illustrating an exemplary embodiment of an integrated pump 1900. For simplicity of illustration, only one compressed air pump is shown. The plurality of compressed air pumps of the integrated pump 1900 can share certain members as described above with reference to FIGS. In this example, the integrated pump 1900 includes a fluid plate 1910, a valve plate 1911, an end plate 1912, a diaphragm 1922 interposed between the valve plate 1911 and the fluid plate 1910, a diaphragm 1922, and a valve plate. And an O-ring 1980 disposed between the fixing plate 1990 and the fluid plate 1910, the valve plate 1911, the end plate 1912, and the diaphragm 1922. The O-ring 1980 can be partially seated. Diaphragm 1922 can be formed from a sheet, which can be formed from an elastic material, PTFE, modified PTFE, or a composite material, preferably a variety of suitable materials that do not react to process fluids. can do. In one embodiment, the diaphragm 1922 may be 0.33 mm (0.013 inches) thick. The fluid can be guided through the fluid attachment member 1985 across the integrated pump 1900. The fluid attachment member 1985 can be connected to the fluid channel through the top support plate 1970 and the attachment plate 1960. The diaphragm 1922 can be driven in a compressed air manner via a compressed air mounting member 1995. The volume of fluid movement (fluid side) within the cavity can be varied depending on the degree of pressure / vacuum applied to the diaphragm 1922. This pressure can be measured by a pressure nut 1950.

  One skilled in the art will appreciate that the number of pumps and types of pumps that can be combined in this manner are not limited to those shown. For example, a motor driven pump forms two or more perforations, such as one perforation for each pump in a single block, and two or more rolling diaphragm pumps with a single control board. Can be combined by bolting them together. In some cases, practical considerations such as complexity in the combination of pumps, and practical considerations regarding the benefits resulting from such combinations may affect the number of pumps to be combined. Can do. For example, if the cost when two separate pumps are used in the derivation system is X, the cost is a fraction of X when the two pumps are combined. However, in the case of a combination of four pumps, the fraction of X can be increased. As the number of pumps combined increases, it becomes a challenge to reduce the value of combining them. There are points where the fraction of X is sufficiently close to X, and there are points where the saving effect due to the combination of a plurality of pumps can be ignored.

  The combination of multiple pumps that can operate independently of each other can provide many advantages. For example, an integral pump requires a smaller footprint compared to the total footprint of multiple individual pumps. In addition, the integrated pump can simplify the wiring / cable configuration, thereby reducing installation time / assembly time / maintenance time. Furthermore, the integral pump can reduce the overall system cost based at least on the sharing of material within each unit of the integral pump.

  Although various embodiments of a modular, flexible, smart, cost-effective and high-performance derivation system have been described herein, those skilled in the art will recognize various embodiments according to the present invention. It will be understood that various modifications and variations can be made without departing from the spirit and scope of the embodiments. Those skilled in the art will appreciate that the various features and aspects described herein can be implemented independently of each other and can be implemented in various combinations. Let's go. Accordingly, the disclosure within this specification, including the accompanying drawings, is not intended to limit the invention but to illustrate the invention. Such modifications are within the scope of the present invention. Accordingly, the scope of the invention should be determined by the claims and their equivalents.

DESCRIPTION OF SYMBOLS 100 Multistage pump 105 Feed stage part 110 Outlet stage part 112 Pressure sensor 120 Filter 125 Inlet valve 130 Isolation valve 135 Barrier valve 140 Purge valve 145 Vent valve 147 Outlet valve 150 Feed pump 180 Outlet pump

Claims (26)

A customizable derivation system,
A smart controller configured to control a plurality of pumps in a semiconductor manufacturing process that is sensitive to defects in a printed pattern, the plurality of pumps comprising at least one compressed air pump and at least one pump A smart controller, including a motor driven pump;
A plurality of lines for connecting the smart controller and the track and for connecting the smart controller and various devices;
Comprising
The various devices include a pump head for the at least one compressed air pump and a pump head for the at least one motor-driven pump;
When the smart controller switches one of the plurality of lines from communication with the first pump to communication with the second pump, the second controller automatically recognizes the second pump and A customizable derivation system characterized by being configured to apply a control scheme corresponding to The customizable derivation system of claim 1.
The first pump is a compressed air pump;
A customizable derivation system, wherein the second pump is a motor driven pump. The customizable derivation system of claim 1.
A customizable derivation system wherein both the first pump and the second pump are motor driven pumps. The customizable derivation system of claim 1.
A customizable derivation system, wherein both the first pump and the second pump are compressed air pumps. The customizable derivation system of claim 1.
The smart controller automatically recognizes the newly connected pump when an interface is connected to the newly connected pump, and applies a control scheme corresponding to the newly connected pump. Configured to be able to
A customizable derivation system, wherein the newly connected pump is a motor driven pump or a compressed air pump. The customizable derivation system of claim 1.
A customizable derivation system, wherein the smart controller comprises an on-board database storing information related to the plurality of pumps. The customizable derivation system of claim 1.
A customizable derivation system, wherein the various devices comprise a filter with a high frequency recognition tag. The customizable derivation system of claim 1.
The plurality of pumps comprises one or more integrated pumps;
Each of the one or more integrated pumps comprises two or more compressed air pumps physically combined with each other as a unit;
The two or more compressed air pumps in the unit shall operate independently of each other;
A customizable derivation system, wherein the two or more compressed air pumps in the unit are controlled independently of each other by the smart controller. The customizable derivation system of claim 8.
A customizable derivation system, wherein the one or more integrated pumps function as a feed pump. The customizable derivation system of claim 8.
A customizable derivation system, wherein the one or more integrated pumps function as derivation pumps. The customizable derivation system of claim 1.
A customizable derivation system characterized in that the switching is due to physical disconnection of the first pump and physical connection of the second pump. The customizable derivation system of claim 1.
A customizable derivation system, wherein the switching is due to instructions received by the smart controller. A customizable derivation system,
A plurality of feed pumps in one set for introducing chemicals used in the semiconductor manufacturing process;
A plurality of derivation pumps forming a set for deriving said chemical substance;
A smart controller configured to control the set of feed pumps and the set of outlet pumps;
Comprising
The set of feed pumps and the set of output pumps comprise one or more integrated pumps;
Each of the one or more integrated pumps comprises two or more compressed air pumps physically combined with each other as a unit;
The two or more compressed air pumps in the unit shall operate independently of each other;
A customizable derivation system, wherein the two or more compressed air pumps in the unit are controlled independently of each other by the smart controller. The customizable derivation system of claim 13.
When the smart controller switches from communication with the first pump to communication with the second pump, the second pump is automatically recognized so that a control scheme corresponding to the second pump can be applied. Customizable derivation system characterized by being configured. The customizable derivation system of claim 14.
The first pump is a compressed air pump;
A customizable derivation system, wherein the second pump is a motor driven pump. The customizable derivation system of claim 14.
A customizable derivation system wherein both the first pump and the second pump are motor driven pumps. The customizable derivation system of claim 14.
A customizable derivation system, wherein both the first pump and the second pump are compressed air pumps. The customizable derivation system of claim 13.
The smart controller automatically recognizes the newly connected pump when an interface is connected to the newly connected pump, and applies a control scheme corresponding to the newly connected pump. Configured to be able to
A customizable derivation system, wherein the newly connected pump is a motor driven pump or a compressed air pump. A customizable derivation system,
A plurality of feed pumps in one set for introducing chemicals used in the semiconductor manufacturing process;
A plurality of derivation pumps forming a set for deriving said chemical substance;
A smart controller configured to control the set of feed pumps and the set of outlet pumps;
Comprising
The set of feed pumps and the set of output pumps comprise one or more integrated pumps;
Each of the one or more integrated pumps comprises two or more compressed air pumps physically combined with each other as a unit;
The two or more compressed air pumps in the unit shall operate independently of each other;
The two or more compressed air pumps in the unit are controlled independently of each other by the smart controller;
The smart controller automatically recognizes the newly connected pump when an interface is connected to the newly connected pump, and applies a control scheme corresponding to the newly connected pump. Configured to be able to
A customizable derivation system, wherein the newly connected pump is a motor driven pump or a compressed air pump. The customizable derivation system of claim 19.
When the smart controller switches from communication with the first pump to communication with the second pump, the second pump is automatically recognized so that a control scheme corresponding to the second pump can be applied. Customizable derivation system characterized by being configured. The customizable derivation system of claim 20.
The first pump is a compressed air pump;
A customizable derivation system, wherein the second pump is a motor driven pump. The customizable derivation system of claim 20.
A customizable derivation system wherein both the first pump and the second pump are motor driven pumps. The customizable derivation system of claim 20.
A customizable derivation system, wherein both the first pump and the second pump are compressed air pumps. The customizable derivation system of claim 20.
A customizable derivation system characterized in that the switching is due to physical disconnection of the first pump and physical connection of the second pump. The customizable derivation system of claim 20.
A customizable derivation system, wherein the switching is due to instructions received by the smart controller. A filtration method comprising:
In a controller of a derivation system comprising a feed pump and a derivation pump; determining an upstream pressure of fluid upstream from a filter located between the feed pump and the derivation pump;
Setting a feed stage fluid pressure with respect to the upstream pressure;
Set the derivation stage fluid pressure against the filtration pressure setpoint;
Opening a valve to allow fluid to flow from the feed side through the filter to the outlet side, wherein the feed stage fluid pressure and the outlet stage fluid pressure generate a pressure differential through the filter; This moves fluid from the feed side to the outlet side through the filter;
Determining an end point of filtration based on a change in fluid pressure at the outlet side;
The filtration method characterized by the above-mentioned.