This invention relates to an apparatus for generating a consistent and stable plasma. More particularly, it relates to an assembly (this assembly is also referred to as an “arc”) for generating a consistent and stable expanding thermal plasma (hereinafter referred to as “ETP”), which assembly is easy to maintain and operate.
Known methods for depositing an adherent coating onto a surface of a substrate by plasma deposition typically comprise passing a plasma gas through a direct current arc plasma generator to form a plasma. A substrate is positioned in an adjoining vacuum chamber (The vacuum chamber is also referred to as the “deposition chamber”). The plasma is expanded into the vacuum chamber towards the substrate. A reactant gas and an oxidant are injected downstream into the expanding plasma. Reactive species formed in the plasma from the oxidant and/or reactant gas contact the surface of the substrate for a period of time sufficient to form an adherent coating.
Plasma sources are used to provide a variety of surface treatments for a number of articles. Examples of such surface treatments include deposition of various coatings, plasma etching, and plasma activation of the surface. An array of multiple plasma sources may be used to coat or treat larger substrate areas. The characteristics of the plasma process are strongly affected by the operating parameters of these plasma sources.
Operating parameters typically used for the current arc design are the flow rate and pressure of the plasma gas, the electrical current applied to the arc and the voltage between cathode and anode. These operating parameters together with the arc geometry and design influence the degree of ionization of the plasma gas and hence surface properties and coating performance of parts coated in a plasma deposition process. In a typical plasma deposition process the gas flow rate and the arc current are controlled and result in control of the operating pressure and voltage.
During plasma treatment, conditions and geometry within the plasma source may drift, i.e. cathode voltage or operating pressure may change without changes in the current or gas flow. These changes can be attributed to a variety of causes within the plasma source. Sources of variability include changes brought about as a result of the erosion of the cathode. Other plasma source components subject to erosion include the cascade plate and the separator plate. During the operation of the plasma source copper can erode from the cascade plate and re-deposit across the insulator leading to reduced resistance between the two isolated plates and ultimately to shorting. Yet another cause leading to resistance changes or shorting of the arc is the presence of water between the electrically isolated plates, e.g. by a failure to exclude water from the environment or by leakage of coolant water into the interior of the plasma source. To counteract such drift, particularly the permanent changes caused by erosion of plasma source components, disruption of the plasma deposition process and disassembly of the plasma source are usually required.
An array of multiple plasma sources may at times be used to coat larger substrate areas. Ideally, the individual plasmas generated by each of the plasma sources in the array should have the same characteristics. In practice, however, source-to-source variation in plasma characteristics is frequently observed. Consequently, articles coated in a plasma deposition device comprising multiple plasma sources can demonstrate undesirable variability in surface coating properties at different locations on the coated substrate surface. Thus there is a need to reduce variability among multiple plasma sources in multi-source plasma deposition devices.
The plasma sources employed in plasma deposition devices have finite lifetimes and must be serviced or replaced periodically. Among typical plasma deposition devices, in order to service (i.e. repair or replace) the plasma source, the plasma deposition chamber must be vented to the atmosphere. Venting the plasma deposition chamber to the atmosphere requires that the plasma deposition process be shut down. This results in downtime and production losses. Furthermore the plasma source design typically comprises a variety of different components, which have to be machined to different tolerances. Thus, in some instances downtime for servicing the plasma source increases due to lack of availability of a component needed as a replacement part.
Typically, drift within a single plasma source cannot be corrected for in real time because such corrections require disruption of the process and disassembly of the plasma source. Where multiple plasma sources are used, minimization of source-to-source variation in the generated plasmas is often desirable. Therefore, what is needed is a simplified apparatus for the generation of a plasma, which apparatus is capable of generating a consistent and stable plasma, is easily serviceable, and which apparatus provides for greater efficiency in plasma mediated surface treatment processes, said efficiency being due in part to a reduction in apparatus downtime during servicing.
In one aspect the present invention relates to an assembly for plasma generation comprising:
(a) a cathode plate comprising a fixed cathode tip, said cathode tip being integral part of said cathode plate;
(b) at least one cascade plate;
(c) at least one separator plate disposed between said cathode plate and said cascade plate;
(d) an anode plate; and
(e) an inlet for a gas;
wherein said cathode plate, separator plate, cascade plate and anode plate are “electrically isolated” from one another, and wherein said electrically isolated cathode plate, separator plate, and cascade plate define a plasma generation chamber, said cathode tip being disposed within said plasma generation chamber.
In another aspect the present invention relates to a deposition apparatus for surface treating of a substrate, the deposition apparatus comprising:
In yet another aspect the present invention relates to an assembly for plasma generation, said assembly comprising:
(a) a retrofittable sub-assembly comprising at least one cathode, at least one cascade plate and at least one of either a separator plate or cathode housing, said separator plate or cathode housing being disposed between said cathode plate and said cascade plate;
(b) an anode plate; and
(c) an inlet for a gas;
wherein said cathode, separator plate or cathode housing, cascade plate and anode plate are electrically isolated from one another, and wherein said electrically isolated catode plate, separator plate or cathode housing, and cascade plate define a plasma generation chamber, said cathode being disposed within said plasma generation chamber.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Various embodiments of this invention have been described in fulfillment of the various needs that the invention meets. It should be recognized that these embodiments are merely illustrative of the principles of various embodiments of the present invention. Numerous modifications and adaptations thereof will be apparent to those skilled in the art without departing from the spirit and scope of the present invention. Thus, it is intended that the present invention cover all suitable modifications and variations as come within the scope of the appended claims and their equivalents.
Disclosed herein is an assembly for generating a consistent and stable plasma for surface treatment.
The diameter of the plasma generation chamber 24 is determined by the diameter 30 of the opening at the center of the separator plate 16. In some embodiments, the cathode plate 12, the separator plate 16 and the cascade plate 18 are machined from identical blank plates, so that the thicknesses 32 of all the plates are identical.
The cascade plate 18 further comprises an opening 34 at the center of the plate. The diameter of the opening 34 is substantially smaller than the diameter 30 of the opening in the separator plate 16. Therefore the opening 34 acts as an orifice and restricts the flow of plasma from the plasma generation chamber 24, thereby increasing the pressure in the plasma generation chamber 24. The anode plate 22 is disposed adjacent to the cascade plate 18, which cascade plate 18 is electrically isolated from the anode plate 22 as described above. The anode plate 22 is configured to have a expanded opening 36 aligned at the center of the anode plate 22, wherein the cross section of the opening 36 expands along with the inside surface 38. The anode plate 22 is disposed on a deposition chamber (not shown) by means of fastening bolts 50. In the exemplary embodiment, as shown in
All assembly components, cathode plate 12, separator plate 16, cascade plate 18 and anode plate 22 are electrically isolated. Typically O-rings, spacers (of PVC for example) and central rings made of boron nitride may be employed to seal and isolate the individual components. Any material or combination of materials that serve the purpose of achieving electrical isolations and provide a vacuum seal can be used. In one embodiment, a Viton® gasket 26 together with a central ring made from boron nitride is used to electrically isolate the individual components as well as provide a vacuum seal and water seal to prevent shorting due to moisture. In order to prevent shorting resulting from erosion of the metallic components of the assembly and re-deposition of the eroded metal (e.g. copper metal) in the cascade plate to anode gap, the thickness of the gasket is configured to be larger than the boron nitride central disk. In the case of o-rings and spacers, this can be achieved by increasing the thickness of the o-ring and spacer relative to the central ring. The metal rods 46 used to fasten the components must also be electrically isolated. This can be achieved by using an insulating sleeve, or the rods themselves can be made from an electrically non-conductive material, e.g. a threaded rod made from Garolite® G10.
In a plasma generation process, the temperature of the assembly for plasma generation may be in the range of about 1000 K to about 10,000 K. For an efficient plasma generation process the elements in the plasma generation assembly need to be cooled. The cathode plate 12, separator plate 16 and the cascade plate 18 comprise an electrically and thermally conducting metal, including but not limited to copper (Cu). Any other metal that meets these requirements may also be used, e.g. stainless steel, nickel, nichrome, etc.
The cooling of the cathode plate 12, separator plate 16, cascade plate 18 and the anode plate 22 may be achieved by passing a cooling medium through the different plates to achieve proper cooling. Each plate may have an individual cooling circuit including an inlet and outlet for the cooling medium. In one embodiment of the present invention the assembly for plasma generation comprises a single circuit 40, which circuit comprises at least one cooling medium inlet 42 and one cooling medium outlet 44. Using an identical blank plate for making each of the cathode plate 12, separator plate 16 and the cascade plate 18, the single circuit 40 for the cooling medium may be formed as described in the following sections. In one embodiment, water is used as the cooling medium to cool the assembly for plasma generation. Any other cooling medium that is compatible with the materials of construction of the assembly for plasma generation may also be used.
Referring to
The use of a standardized “blank plate” as a starting point to make each of the three components (cathode plate, separator plate and cascade plate) of the sub-assembly for the plasma generation assembly reduces the burden of keeping customized replacement parts in stock. From a common blank, each component of the sub-assembly is easily machined by drilling additional holes required (e.g. holes for water lines and holes for plasma orifices). Because of fewer components required in stock, easier machinability, and standardized internal water channels, the use of standardized blank plates to prepare individual sub-assembly components reduces the cost and downtime, and simplifies maintenance of the overall plasma generation and surface treatment process. Additionally, the use of a “blank plate” as a starting element for the preparation of sub-assembly components, and the fixed cathode design of the present invention allow for reduced variability of the overall plasma generation and surface treatment process.
As disclosed in the preceding sections, the assembly for plasma generation comprises a sub-assembly comprising the cathode plate, the separator plate and the cascade plate as components of the sub-assembly which may be joined together with an electrically non-conductive fastener 50 (
In the assembly for plasma generation as disclosed in the preceding sections, the cathode plate, the separator plate and the cascade plate form a sub-assembly. The sub-assemblies described in the embodiments described herein are “retrofitable” onto the assembly for plasma generation shown in
A plasma deposition apparatus generally includes a plasma source comprising a plasma generation chamber as described in the preceding sections.
The first assembly 262 comprises a cathode plate 264 comprising a fixed cathode tip 272, at least one cascade plate 268 and at least one separator plate 266 disposed between the cathode plate 264 and the cascade plate 268. The cathode tip 272 is an integral part of the cathode plate 264. The first assembly 262 further comprises an anode plate 270 and an inlet 278 for a gas. In one embodiment, the cathode plate 264, the cascade plate 268, the separator plate 266 and the anode plate 270 are electrically isolated from one another by a Viton® gasket 284 and a boron nitride disk 288. The electrically isolated cathode plate 264, separator plate 266 and cascade plate 268 define a plasma generation chamber 286. In the exemplary embodiment, as shown in
In one embodiment, a power source 280 is connected to the first assembly 262. The power source 280 is an adjustable DC power source that provides the required current and voltage for igniting and maintaining the arc power. The deposition chamber 400 is maintained at a pressure, which is substantially less than the pressure in the first assembly 262 by means of vacuum pumps not shown. In one embodiment, the deposition chamber 400 is maintained at a pressure of less than about 1 torr (about 133 Pa) and, specifically, at a pressure of less than about 100 millitorr (about 0.133 Pa), while the plasma generation chamber 286 is maintained at a pressure of at least about 0.1 atmosphere (about 1.01×104 Pa). As a result of the difference between the pressure in the plasma generation chamber 286 and the pressure in the deposition chamber 400, the plasma generated in the first assembly 262 passes through the exit port 276 and expands into the deposition chamber 400.
Deposition chamber 400 is adapted to contain an article 258 that is to be treated with the plasmas produced by the deposition apparatus 260. In one embodiment, such plasma treatment of article 258 comprises injecting at least one reactive gas into the plasma produced by apparatus 260 and depositing at least one coating on a surface of article 258. The surface of article 258 upon which the plasma impinges may be either planar or non-planar. Apparatus 260 is capable of providing other plasma treatments in which at least one plasma impinges upon a surface of an article 258. Other plasma treatments include but are not limited to plasma etching at least one surface of article 258, heating article 258, lighting or illuminating article 258, and functionalizing (i.e., producing reactive chemical species) a surface of article 258.
The second assembly 362 comprises a cathode plate 364 comprising a fixed cathode tip 372, at least one cascade plate 368 and at least one separator plate 366 disposed between the cathode plate 364 and the cascade plate 368. The cathode tip 372 is an integral part of the cathode plate 364. The second assembly 362 further comprises an anode plate 370 and an inlet 378 for a gas. In one embodiment, the cathode plate 364, the cascade plate 368, the separator plate 366 and the anode plate 370 are electrically isolated from one another by a Viton® gasket 384 and a boron nitride disk 388. The electrically isolated cathode plate 364, separator plate 366 and cascade plate 368 define a plasma generation chamber 386. In the exemplary embodiment, as shown in
In one embodiment, a power source 380 is connected to the first assembly 362. The power source 380 is an adjustable DC power source that provides the required current and voltage for igniting and maintaining the arc power. The deposition chamber 400 is maintained at a pressure, which is substantially less than the pressure in the first assembly 362 by means of vacuum pumps not shown. In one embodiment, the deposition chamber 400 is maintained at a pressure of less than about 1 torr (about 133 Pa) and, specifically, at a pressure of less than about 100 millitorr (about 0.133 Pa), while the plasma generation chamber 386 is maintained at a pressure of at least about 0.1 atmosphere (about 1.01×104 Pa). As a result of the difference between the pressure in the plasma generation chamber 386 and the pressure in the deposition chamber 400, the plasma generated in the first assembly 362 passes through the exit port 376 and expands into the deposition chamber 400.
The treated or coated substrate may be of any suitable material including metal, semiconductor, ceramic, glass or plastic. Plastics and other polymers are commercially available materials possessing physical and chemical properties that are useful in a wide variety of applications. For example, polycarbonates are a class of polymers, which, because of their excellent breakage resistance, have replaced glass in many products, such as automobile head-lamps, safety shields, eyewear, and windows. However, many polycarbonates also have properties, such as low abrasion resistance and susceptibility to degradation from exposure to ultraviolet (UV) light. Thus, untreated polycarbonates are not commonly used in applications such as automotive and other windows, which are exposed, to ultraviolet light and physical contact from a variety of sources. In one embodiment, the coated substrate 202 is a thermoplastic such as polycarbonate, copolyestercarbonate, polyethersulfone, polyetherimide or acrylic. The term “polycarbonate” in this context including homopolycarbonates, copolycarbonates and copolyestercarbonates.
Various embodiments of this invention have been described in fulfillment of the various needs that the invention meets. It should be recognized that these embodiments are merely illustrative of the principles of various embodiments of the present invention. Numerous modifications and adaptations thereof will be apparent to those skilled in the art without departing from the spirit and scope of the present invention. Thus, it is intended that the present invention cover all suitable modifications and variations as come within the scope of the appended claims and their equivalents.
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