This invention to a gravity-fed in-line processing system useful for, inter alia, rapidly coating plastic substrates such as plastic flatware and cellular telephone housings.
Conventional systems and methods of applying coatings to substrates such as metallizing insulative substrates include electroplating, electroless plating, painting, arc-spray, evaporative vacuum metallization, and sputter vacuum metallization. These systems and processes are usually batch oriented. Typical batch oriented systems require parts or substrates to be placed on racks for insertion into a batch chamber. The batch chamber door is opened, a rack of parts is inserted into the chamber, and the door is then closed and sealed. Thereafter, coating takes place, and after coating, the batch chamber door is again opened, and the rack of parts is removed manually and unloaded.
One disadvantage of batch oriented production systems is that during the coating process, other operations cease, creating down time. Also, the cycle time is long, and large production run volumes are required for the system to be cost effective. Batch oriented systems result in large work-in-process inventories and a large number of at-risk parts before process quality can be assessed.
Some of these disadvantages and limitations may be overcome by so-called “in-line” systems that integrate vacuum metallization “in-line” with a parts molding machine. However, conventional systems are often expensive and complex. Moreover, such systems often include conveyors, robot arms within the system, and/or gates with valves and seals that utilize up and down and/or sliding motion which are subject to excess wear, malfunction and necessitate frequent replacement of parts over the life of the system. The conveyors, and robot arms within the system, can also contaminate the highly sensitive vacuum chambers.
It is therefore an object of this invention to provide an improved system for applying coatings to substrates and particularly for metallizing plastic parts.
It is a further object of this invention to provide a truly in-line metallizing system that may be physically located adjacent a parts molding machine.
It is a further object of this invention to provide such a system that is rapid, automated, and continuous, with reduced cycle time and reduced down time.
It is a further object of this invention to provide such a system which eliminates the need for a conveyor or a robot arm within the system.
It is a further object of this invention to provide such a system with improved and more robust gates or valves.
This invention results from the realization that an improved, faster, more robust, higher quality and more reliable in-line metallization processing system can be achieved with a system that utilizes gravity instead of mechanical conveyors, or robot arms within, and which utilizes rotary barrel gate valves in place of conventional gates and valves, and which may be located adjacent a molding machine.
This invention features a gravity-fed in-line continuous processing system including at least one processing chamber disposed between a first load lock and a second load lock, with the second load lock disposed lower than the first load lock. The system may include a first device for isolating the processing chamber from the first load lock, a second device for isolating the processing chamber from the second load lock, and at least one track through the processing chamber and the first and second load locks, with the track structured and arranged such that an article slides thereon under the force of gravity.
In one embodiment, the processing chamber, the first load lock and the second load lock may all be angled with respect to the horizontal, or the track may be angled with respect to the horizontal. The track, the processing chamber, the first load lock and the second load lock, or any combination thereof, may be angled with respect to the horizontal. The angle with respect to the horizontal may be greater than 33° but less than 43°. The angle with respect to the horizontal may be about 40°. The first load lock may be an input load lock, and the second load lock may be an output load lock. The first device may be structured and arranged to prevent the article from sliding under the force of gravity when the first device is closed. The second device may be structured and arranged to prevent the article from sliding under the force of gravity when the second device is closed. The first device may be structured and arranged to allow the article to slide on the track from the first load lock to the processing chamber when the first device is open. The second device may be structured and arranged to allow the article to slide on the track from the processing chamber to the second load lock when the second device is open.
The first device may be a first rotary barrel gate valve and the second device may be a second rotary barrel gate valve. The system may include a plurality of tracks through the processing chamber and the first and second load locks, and all tracks may be angled with respect to the horizontal. The plurality of tracks may be structured and arranged such that articles in each of the plurality of tracks slide thereon under the force of gravity for simultaneously processing a plurality of articles. The plurality of tracks are typically parallel to one another and the parallel tracks of the first load lock, the tracks of the processing chamber, and the tracks of the second load lock are aligned with one another.
The system may include an input tray disposed adjacent the first load lock. An output tray may be disposed adjacent the output load lock. The processing chamber may be a vacuum sputtering chamber. The first load lock and the second load lock may be structured and arranged for venting from a first pressure to a second pressure. The first pressure may be a vacuum and the second pressure may be atmospheric pressure. The first load lock and the second load lock may be structured and arranged for evacuating from a first pressure to a second pressure. The first pressure may be atmospheric pressure and the second pressure may be a vacuum. The system may include a third device between the first load lock and atmosphere and a fourth device between the second load lock and atmosphere. The third device may be a third rotary barrel gate valve and the fourth device may be a fourth rotary barrel gate valve. The article to be processed may be any sputterable part such as plastic, polystyrene, and in particular it may be polystyrene plastic cutlery. The system may further include a take-out robot for transferring articles from an injection molding machine to the input tray. The first load lock, the second load lock, the first device, the second device and the processing chamber may be sequenced such that sets of articles may be processed simultaneously. Each of the processing chamber, the first and second load locks and the first and second devices may be angled with respect to the horizontal. The first device may include a body, at least one passage through the body defining an inlet and an outlet, a first actuator for rotating the body, a second actuator for translating the body, and a sealing portion on the body for sealing the body with respect to an opening into a chamber adjacent the body.
This invention further features a gravity-fed in-line continuous processing system including at least one processing chamber disposed between a first load lock and a second load lock, the second load lock disposed lower than the first load lock, a first device for isolating the processing chamber from the first load lock and a second device for isolating the processing chamber from the second load lock. The processing chamber, the first load lock, the second load lock, the first device and the second device may all be angled with respect to the horizontal, each having a plurality of tracks with the plurality of tracks structured and arranged such that a plurality of articles slide thereon under the force of gravity from the first load lock, through the processing chamber, and to the second load lock.
This invention further features a gravity-fed in-line continuous processing system including at least one vacuum sputtering chamber disposed between a first load lock and a second load lock, the second load lock disposed lower than the first load lock. A first rotary barrel gate valve for isolating the vacuum sputtering chamber from the first load lock may be included, the first rotary barrel gate valve structured and arranged to prevent an article from sliding under the force of gravity when the first rotary barrel gate valve is closed and to allow the article to slide therethrough under the force of gravity when the first rotary barrel gate valve is open. A second rotary barrel gate valve for isolating the vacuum sputtering chamber from the second load lock may be included, the second rotary barrel rotary barrel gate valve structured and arranged to prevent an article from sliding under the force of gravity when the second rotary barrel gate valve is closed and to allow the article to slide therethrough under the force of gravity when the second rotary barrel gate valve is open.
This invention also features a gravity-fed in-line continuous processing system including at least one processing chamber disposed between a first load lock and a second load lock, the second load lock disposed lower than the first load lock. There may be included a first rotary barrel gate valve for isolating the processing chamber from the first load lock, the first rotary gate valve structured and arranged to prevent an article from sliding under the force of gravity when the first rotary gate valve is closed and to allow the article to slide therethrough under the force of gravity when the first rotary gate valve is open. There may be included a second rotary barrel gate valve for isolating the processing chamber from the second load lock, the second rotary gate valve structured and arranged to prevent the article from sliding under the force of gravity when the second rotary gate valve is closed and to allow the article to slide therethrough under the force of gravity when the second rotary gate valve is open. There may further be included a third rotary barrel gate valve for isolating the first load lock from atmosphere, the third rotary gate valve structured and arranged to prevent the article from sliding under the force of gravity when the third rotary gate valve is closed and to allow the article to slide therethrough under the force of gravity when the third rotary gate valve is open. An input tray may terminate at the third rotary barrel gate valve. A fourth rotary barrel gate valve may be included for isolating the second load lock from atmosphere, the fourth rotary gate valve structured and arranged to prevent the article from sliding under the force of gravity when the fourth rotary gate valve is closed and to allow the article to slide therethrough under the force of gravity when the fourth rotary gate valve is open. An output tray may be adjacent the fourth rotary barrel gate valve, and a plurality of tracks may be angled through the first load lock, the processing chamber, and the second load lock interconnecting the input tray and the output tray to urge, under the force of gravity, articles through the first load lock, the processing chamber, and the second load lock.
This invention also features a gravity-fed in-line continuous processing system including at least one processing chamber module disposed between a first load lock module and a second load lock module, the second load lock module disposed lower than the first load lock module. A first device may be included for isolating the processing chamber module from the first load lock module, a second device may be included for isolating the processing chamber module from the second load lock module, and there may be at least one track through the processing chamber module and the first and second load lock modules, the track structured and arranged such that an article slides thereon under the force of gravity.
This invention further features a gravity-fed in-line continuous processing system including at least one processing chamber including at least one track therethrough, with the track structured and arranged such that an article slides thereon under the force of gravity. The processing chamber may be angled with respect to the horizontal and the at least one track may be angled with respect to the horizontal.
This invention further features a gravity-fed in-line continuous processing system including means for processing disposed between a first means for alternating between a first pressure and a second pressure, and a second means for alternating between a first pressure and a second pressure. The first pressure may be atmospheric pressure and the second pressure may be a vacuum. Alternatively, the first pressure may be a vacuum and the second pressure may be atmospheric pressure. The second means for alternating may be disposed lower than the first means for alternating. There may be a first means for isolating the means for processing from the first means for alternating and a second means for isolating the means for processing from the second means for alternating. The system may further include at least one track through the means for processing and the first and second means for alternating. The track may be structured and arranged such that an article slides thereon under the force of gravity.
This invention further features a gravity-fed in-line continuous processing system including at least one means for processing disposed between a first means for alternating between a first pressure and a second pressure, and a second means for alternating between a first pressure and a second pressure. The first pressure may be atmospheric pressure and the second pressure a vacuum. The second means for alternating may be disposed lower than the first means for alternating. There may be a first means for isolating the means for processing from the first means for alternating. The first means for isolating may be structured and arranged to prevent an article from sliding under the force of gravity when the first means for isolating is closed, and to allow the article to slide therethrough under the force of gravity when the first means for isolating is open. There may also be a second means for isolating the means for processing from the second means for alternating. The second means for isolating may be structured and arranged to prevent the article from sliding under the force of gravity when the second means for isolating is closed and to allow the article to slide therethrough under the force of gravity when the means for isolating is open. There may be a third means for isolating the first means for alternating from atmosphere. The third means for isolating may be structured and arranged to prevent the article from sliding under the force of gravity when the third means for isolating is closed, and to allow the article to slide therethrough under the force of gravity when the third means for isolating is open. An input tray may terminate at the third means for isolating. A fourth means for isolating may isolate the second means for alternating from atmosphere. The fourth means for isolating may be structured and arranged to prevent the article from sliding under the force of gravity when the fourth means for isolating is closed, and to allow the article to slide therethrough under the force of gravity when the fourth means for isolating is open. An output tray may be adjacent the fourth means for isolating. A plurality of tracks may be angled through the means for alternating, the means for processing, and the second means for alternating interconnecting the input tray and the output tray to urge, under the force of gravity, articles through the first means for alternating, the means for processing, and the second means for alternating.
This invention also features a gravity-fed in-line continuous processing system including at least one processing chamber isolatable with respect to first and second chambers and means for urging an article from the first chamber, through the processing chamber, and to the second chamber under the force of gravity.
This invention further features a method for coating substrates, the method comprising providing at least one processing chamber and disposing the processing chamber between a first load lock and a second load lock. The second load lock may be disposed lower than the first load lock. The method further includes isolating the processing chamber from the first load lock with a first device, isolating the processing chamber from the second load lock with a second device, and providing at least one track through the processing chamber and the first and second load locks and structuring and arranging the track such that an article slides thereon under the force of gravity. The method may further include the step of angling the processing chamber, the first load lock and the second load lock with respect to the horizontal. The angle with respect to the horizontal may be greater than 33° but less than 43°. The angle with respect to the horizontal may be about 40°. The method may further include angling the at least one track with respect to the horizontal. The first load lock may be an input load lock and the second load lock may be an output load lock. The step of isolating the processing chamber from the first load lock may be carried out by a first device, and the step of isolating the processing chamber from the second load lock may be carried out by a second device. The first and second devices may be rotary barrel gate valves.
The method may further include structuring and arranging the first device and the second device to prevent the article from sliding under the force of gravity when the first device is closed. The method of this invention may further include structuring and arranging the first and second devices to allow the article to slide on the track from the first load lock to the processing chamber when the first device is open. The first device may be a first rotary barrel gate valve and the second device may be a second rotary barrel gate valve. The method may further include the steps of providing a plurality of tracks through the processing chamber and the first and second load locks, angling all tracks with respect to the horizontal, and structuring and arranging each of the plurality of tracks such that articles in each of the plurality of tracks slide thereon under the force of gravity for simultaneously processing a plurality of articles. The plurality of tracks may be parallel to one another. The method may further include the steps of aligning the parallel tracks of the first load lock, the tracks of the processing chamber, and the tracks of the second load lock with one another, disposing an input tray adjacent the first load lock, and disposing an output tray adjacent the output load lock. The method may further include structuring and arranging the first load lock and the second load lock for alternating between a first pressure and a second pressure. The first pressure may be a vacuum and the second pressure may be atmospheric pressure. The method may also include providing a third device between the first load lock and atmosphere and a fourth device between the second load lock and atmosphere, where the third device is a third rotary barrel gate valve and the fourth device is a fourth rotary barrel gate valve. The method further include sequencing the first load lock, the second load lock, the first device, the second device and the processing chamber such that sets of articles may be processed simultaneously.
The subject invention, however, in other embodiments, need not achieve all these objectives and the claims hereof should not be limited to structures or methods capable of achieving these objectives.
Other objects, features and advantages will occur to those skilled in the art from the following description of a preferred embodiment and the accompanying drawings, in which:
Aside from the preferred embodiment or embodiments disclosed below, this invention is capable of other embodiments and of being practiced or being carried out in various ways. Thus, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings.
One gravity-fed in-line continuous processing system in accordance with the present invention is shown in
One embodiment of this invention system 10,
Any combination of processing chamber modules and a load lock modules may be used with the system of the subject invention, thus providing flexibility for the system user. For example, the system may include a series of load locks and processing chambers in order to end up with a thicker part coating than could be achieved with only one processing chamber and using conventional coating methods.
System 10,
System 10 includes at least one track or chute 22 through at least one of processing chamber 12 and first and second load locks 14 and 16, with track 22 structured and arranged such that article or part 24 slides on track 22 under the force of gravity. Track 22 is shown in phantom cross-section and in exemplary fashion in first load lock 14 of
In one embodiment, processing chamber 12 is a vacuum sputtering chamber including a cathode and shield assembly for metallization on at least one side of article 24 as is known to those skilled in the art, although the processing chamber 12 of this invention is not limited to a vacuum sputtering chamber or to a particular coating or to coating on one side only. Article 24 to be coated may be any sputterable part, such as plastic or polystyrene. The present invention has been successfully used to coat or metallize polystyrene plastic cutlery, such as spoons, knives and forks, with stainless steel. The system of the present invention may further include input tray 40 and output tray 42 as shown in
When first device 18 is closed,
In one preferred embodiment, first and second devices 18 and 20 are rotary barrel gate valves as shown in
First and second devices 18 and 20 (i.e. rotary barrel gate valves) operate with long durability and with high reliability. Each gate valve is interlocked or sequenced to detect full closure, minimizing the risk of direct passing of atmosphere into processing chamber 12, for example, should part 24 become lodged in a gate valve. If part 24 does get lodged in this manner, system 10 halts and an error condition is reported indicating the reason for the error.
In accordance with one embodiment of the present invention, system 10 may include third device 18′,
Each of processing chamber 12, first and second load locks 14, 16, and first and second devices 18, 20 may include at least one track 22. Each of processing chamber 12, first and second load locks 14 and 16, and first and second devices 18 and 20 may include a plurality of tracks 22a, 22b . . . 22n,
Tracks 22a, 22b . . . 22n of first load lock 14, corresponding tracks, i.e. 22a′, 22b′ . . . 22n′ of processing chamber 12 and corresponding tracks i.e. 22a″, 22b″ . . . 22n″ of second load lock 16 are aligned with one another. Each of tracks 22a, 22b . . . 22n, are parallel to one another, as are each of tracks 22a′, 22b′ . . . 22n′ and each of tracks 22a″, 22b″ . . . 22n″. The parallel layout of the tracks permits more tracks to be added by adding width to system 10, and by adding length to the first and second devices 18, 20 (and third and fourth devices 18′, 20′) where, as noted above, both first and second devices 18, 20 also include tracks, i.e. 22a″″, 22b″″ . . . 22n″″ (not shown) corresponding to and aligned with tracks of adjacent load locks or processing chamber.
Tracks 22a, 22b . . . 22n are arranged in groups 70, 72, 74, 76 . . . with members 80, 82, 84 . . . 84n installed between groups to provide structural support, as exemplified by
Those skilled in the art will recognize that a system in accordance with the present invention may be comprised of processing chamber 12 alone including at least one track, if contamination during processing is not a concern. In such a case, processing chamber 12 may be angled with respect to the horizontal, or track 22 may be angled with respect to the horizontal, or both processing chamber 12 and track 22 may be angled with the horizontal.
Gravity-fed in-line continuous processing system 10 of this invention,
Applying a metal coating to a clear polystyrene cutlery, for example, by metallization, can be accomplished in a vastly improved manner utilizing this invention. The invention assures high quality, high adhesion, and an overall more robust process.
The operation of system 10 and method of the invention is described as follows. Freshly molded parts or articles 24a, 24b . . . 24n (not shown) are placed on input tray 40 by takeout robot 54,
Notably, in accordance with the present invention, all portions of system 10, namely rotary barrel gate valve 18′, input load lock 14, rotary barrel gate valve 18, processing chamber 12, rotary barrel gate valve 20, output load lock 16, and rotary barrel gate valve 20′ are interlocked or sequenced such that sets of articles may be processed simultaneously. This makes the system more efficient and continuous.
Particularly, one sequence for use in system 10 is shown in
In one example, the opening of rotary barrel gate valve 18′,
The sequence just described is for system 10,
A schematic three-dimensional representation of system 10 of this invention, without take out robot or output tray, is shown in
For system 10 of this invention, it is useful to use first, second, third and fourth devices 18, 18′, 20′, 20,
Rotary barrel gate valve 100 includes body 102,
Passage 104 includes at least one track or chute 120. In one embodiment, a plurality of passages 104, 104a . . . 104n define a plurality of inlets 106, 106a . . . 106n and outlets 108, 108a . . . 108n. Each of the plurality of passages 104, 104a . . . 104n includes at least one track or chute 120 therein, and each passage 104, 104a . . . 104n includes a plurality of tracks or chutes 120, 120a . . . 120n, 120aa, 120ab . . . 120an, . . . 120na, 120nb . . . 120nn. Such an embodiment also includes a plurality of sealing portions 116, 116a . . . 116n,
In one embodiment, sealing portion 116,
When rotary barrel gate valve 100 is open,
Rotary barrel gate valve 100 is moved from closed,
When rotary barrel gate valve 100 is closed,
As described herein, a “chamber” could be an input load lock or an output load lock or atmosphere, and the term “chamber” as used herein is not necessarily limited to a processing chamber. For example, in
For use with rotary barrel gate valve 100 actuator 110,
As noted, the number of chambers or modules of system 10 in accordance with this invention may be increased or decreased and articles other than plastic cutlery may be coated. Other types of processing chambers may be used or added to the system. Also, other types of load and unload locks may be used.
Although specific features of the invention are shown in some drawings and not in others, this is for convenience only as each feature may be combined with any or all of the other features in accordance with the invention. The words “including”, “comprising”, “having”, and “with” as used herein are to be interpreted broadly and comprehensively and are not limited to any physical interconnection. Moreover, any embodiments disclosed in the subject application are not to be taken as the only possible embodiments. Other embodiments will occur to those skilled in the art and are within the following claims.
In addition, any amendment presented during the prosecution of the patent application for this patent is not a disclaimer of any claim element presented in the application as filed: those skilled in the art cannot reasonably be expected to draft a claim that would literally encompass all possible equivalents, many equivalents will be unforeseeable at the time of the amendment and are beyond a fair interpretation of what is to be surrendered (if anything), the rationale underlying the amendment may bear no more than a tangential relation to many equivalents, and/or there are many other reasons the applicant can not be expected to describe certain insubstantial substitutes for any claim element amended.
This application is a divisional of patent application Ser. No. 10/400,775 filed Mar. 27, 2003 entitled GRAVITY-FED IN-LINE CONTINUOUS PROCESSING SYSTEM AND METHOD which claims priority of and is related to U.S. Provisional Patent Application Ser. No. 60/368,818, filed Mar. 29, 2002. This application is also related to the U.S. patent application entitled ROTARY BARREL GATE VALVE, Ser. No. 10/401,001 filed Mar. 27, 2003 and hereby incorporated by reference herein, and which also claims priority to U.S. Provisional Patent Application Ser. No. 60/368,818 filed Mar. 29, 2002.
Number | Date | Country | |
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60368818 | Mar 2002 | US |
Number | Date | Country | |
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Parent | 10400775 | Mar 2003 | US |
Child | 10975910 | Oct 2004 | US |