Embodiments of the present disclosure generally relate to substrate processing equipment.
Within substrate processing equipment, a gate valve may be utilized, for example, in multi-chamber processing systems to selectively isolate or couple adjacent volumes. For example, current multi-chamber processing apparatus typically include semiconductor processing slit valves and gate valves to isolate pressure controlled processing volumes during transfer of work parts or repair of one or more fluidly connected processing regions. However, the inventors have observed that the seals and sealing surfaces of the conventional valves are limited in their sealing ability, especially if an interfering material such as a continuous substrate is present at the seal interface. Ineffective leak control is especially problematic in multiple processing volumes, when the process in each chamber uses a different pressure, or when only one of the processing volumes needs to be vented and cooled for service or due to emergency process stops.
Accordingly, the inventors have provided an improved gate valve.
Embodiments of gate valves and methods for using same are provided herein. In some embodiments, a gate valve includes: a body; a plurality of seals disposed within the body and configured to move between a closed position and an open position; a plurality of volumes defined by the plurality of seals and the body; a gas inlet disposed through a first side of the body and fluidly coupled to an innermost one of the plurality of volumes; and a gas outlet disposed through a second side of the body opposite the first side and fluidly coupled to other ones of the plurality of volumes.
In some embodiments, a gate valve for processing a continuous substrate includes: a body having a first wall, a second wall opposite the first wall, an opening disposed from a first surface to an opposing second surface of the body, wherein the opening is configured to hold and convey a continuous substrate; a plurality of seals movably disposed between the first wall and the second wall, configured to move between a closed position to seal the opening, and an open position that reveals the opening; a plurality of volumes disposed between adjacent ones of the plurality of seals and defined by the plurality of seals and the body; a gas inlet disposed through a first side of the body and fluidly coupled to an innermost one of the plurality of volumes on the first side of the body, wherein the gas inlet fluidly coupled to an innermost one of the plurality of volumes; and a gas outlet disposed through a second side of the body opposite the first side and fluidly coupled to other ones of the plurality of volumes disposed on either side of the innermost one of the plurality of volumes.
In some embodiments, a processing system for processing a continuous substrate includes: a first chamber for processing a continuous substrate; a second chamber for processing the continuous substrate; and a gate valve coupling the first chamber to the second chamber and having an opening through which the continuous substrate can extend between the first chamber and the second chamber, wherein the gate valve is as described in any of the embodiments disclosed herein, and wherein a first side the body is coupled to the first chamber and a second side of the body is coupled to the second chamber.
In some embodiments, a method of processing a continuous substrate includes: processing a continuous substrate in at least one of a first process chamber or a second process chamber coupled to the first process chamber through a gate valve, wherein the continuous substrate is simultaneously disposed through each of the first process chamber, the gate valve, and the second process chamber; and closing the gate valve while the continuous substrate is disposed therethrough to substantially isolate the first process chamber from the second process chamber.
Other and further embodiments of the present disclosure are described below.
Embodiments of the present disclosure, briefly summarized above and discussed in greater detail below, can be understood by reference to the illustrative embodiments of the disclosure depicted in the appended drawings. However, the appended drawings illustrate only typical embodiments of the disclosure and are therefore not to be considered limiting of scope, for the disclosure may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. The figures are not drawn to scale and may be simplified for clarity. Elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
Embodiments of gate valves and methods for using same are provided herein. The disclosed gate valves and methods of using same advantageously benefit vacuum processing of continuous web, film, sheet, ribbon-like fiber and other thin or flat substrates. For some applications, maintaining a continuous substrate, without breaks or joints, across one or more sealing interfaces that correspond to one or more openings where material is transferred into or out of a processing volume is beneficial. Conventional semiconductor processing slit valves and gate valves are used for transferring discrete work parts into pressure controlled processing volumes. These conventional designs, and the seals and sealing surfaces specifically, are limited in their capacity to maintain adequate leak integrity if interfering material is present at the seal interface. For some applications such as chemical vapor infiltration of ceramic fibers, conveying one or more tow across multiple vacuum breaks such that the start of the tow (e.g., an untwisted bundle of continuous filaments) may be at atmospheric pressure, a middle section at reduced pressure, and the end of the tow at atmospheric pressure is advantageous. The foregoing arrangement allows the process to pause and for substrate loading adjustments, or repairs to be made without bringing the furnace to atmospheric pressure. The disclosed gate valve is capable of producing the pressure gradient without compromising the physical integrity of the continuous substrate at the sealing interface. Furthermore, keeping the furnace hot when the processing volumes are not in use is beneficial for system utilization and furnace component reliability.
The gate valves of the present disclosure may be used in any application in which a conventional gate valve may be used, for example in applications in which throttling the flow of a gas between two adjacent volumes is desirable or advantageous. In a non-limiting application, the disclosed gate valve may be disposed between chambers in a two process chamber system, or other suitable process chambers that require a gate valve. For example,
The illustrative two process chamber system 100 includes a first chamber 110 (e.g., a process chamber) having a first chamber volume 114 within a first chamber body (wall 120). In some embodiments, a substrate feedthrough 150 may be provided for conveying a continuous substrate between the first chamber volume 114 and a volume disposed outside of the first chamber 110 (e.g., an adjacent process chamber, a substrate handler, or the like). The system 100 also includes a second chamber 130 (e.g., a process chamber) having a second chamber volume 134 within a second chamber body (wall 140). In some embodiments, a substrate feedthrough 170 may be provided for conveying the continuous substrate between the second chamber volume 134 and a volume disposed outside of the second chamber 130 (e.g., an adjacent process chamber, a substrate handler, or the like). First chamber 110 and second chamber 130 are selectively fluidly coupled to each other via a gate valve 102.
In operation, a continuous substrate 154 is conveyed through substrate feedthroughs 150 and 170, via an opening 106 of the gate valve. The continuous substrate 154 may be processed in the first chamber volume 114 at a first chamber pressure, conveyed to the second chamber volume 134 through the gate valve 102, and processed in the second chamber volume 134 at a second chamber pressure. In some embodiments, the first chamber pressure and the second chamber pressure are the same. In other embodiments, the first chamber pressure and the second chamber pressure are different.
The gate valve 102 is configured to provide selective isolation between the first chamber volume 114 and the second chamber volume 134. For example, isolation between the first chamber volume and the second chamber volume may be desired when one of the chamber volumes needs to be at atmospheric pressure and temperature in order to repair the affected chamber, perform substrate loading adjustments in one of the chambers, or due to an emergency stop. The gate valve 102 includes a plurality of sealing members (four sealing members 104 shown in
The gate valve 200 may further include a plurality of seals 212 disposed between the first surface 208 and the second surface 210 of the body 202 proximate the opening 206. In some embodiments, for example, as depicted in
The gate valve may further include a gas inlet 232 having a valve disposed through the first side 218 of the body and fluidly coupled to an innermost one of the plurality of volumes 238 (e.g., a central one of the volumes 238). The gate valve may also include a gas outlet 234 disposed through the second side 220 of the body and fluidly coupled to other ones of the plurality of volumes 238 disposed on opposite sides of the central volume 238. A purge gas source 242 (shown in
In operation, a continuous substrate 154 may be processed in the first and second chamber volumes 114, 134, as discussed above. As depicted in
As depicted in
Each sealing member 305 may be independently controlled to provide individualized flow conditions (e.g., individualized control of mass flow, volume flow, pressure, etc.) to each one of the other ones of the plurality of volumes 238. Accordingly, in some embodiments, mass flow controllers, volume flow controllers, or pressure regulators may be coupled to the volumes disposed between the angled walls 312.
In some embodiments, sealing members 305 are pneumatically controlled between at least the first position in which the valve is fully open and the second position in which the valve is fully closed. In some embodiments, the sealing members 305 may be controlled by other mechanisms, for example servo motors. In the exemplary open position depicted on
In the exemplary closed position, depicted in
In the exemplary closed position depicted in
In operation, a method of processing a continuous substrate using the above disclosed apparatus includes processing a continuous substrate in at least one of a first process chamber or a second process chamber coupled to the first process chamber through a gate valve. The continuous substrate is simultaneously disposed through each of the first process chamber, the gate valve, and the second process chamber. The gate valve can be closed while the continuous substrate is disposed therethrough to substantially isolate the first process chamber from the second process chamber. In some embodiments, the first process chamber is maintained at a vacuum pressure and a pressure of the second process chamber can be increased while substantially maintaining the pressure in the first process chamber. In some embodiments, the pressure of the second process chamber can be increased to substantially atmospheric pressure while substantially maintaining the pressure in the first process chamber. In some embodiments, service can be performed on the second process chamber while substantially maintaining the pressure in the first process chamber.
Thus, embodiments of improved gate valves and methods of using the same have been provided herein. The inventive gate valves and methods of using may advantageously ensure that a non-affected chamber of a system of chambers may remain at a processing pressure, different from, for example the atmospheric conditions required for the affected chambers.
While the foregoing is directed to embodiments of the present disclosure, other and further embodiments of the disclosure may be devised without departing from the basic scope thereof.
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/035735 | 6/2/2017 | WO | 00 |
Number | Date | Country | |
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62344970 | Jun 2016 | US |