THIN FILM COATING METHOD AND THE MANUFACTURING LINE FOR ITS IMPLEMENTATION
First Claim
1. A method of applying thin film coatings on substrates, consisting of substrate holders and consequent movement of substrate holders through process chambers of a manufacturing line comprising the following steps:
- (a) Fastening a substrate to a substrate holder;
(b) the substrate holder enters an inlet airlock chamber of low vacuum of the manufacturing line, after which a first door of the airlock chamber closes;
(c) the substrate holder retreats and a removable coupling of said substrate holder connects to a mating part of a coupling installed on a rotating shaft of the first door of the airlock chamber, said rotating shaft being driven by an electric motor installed on said first door of the airlock chamber;
(d) an electric motor spins a drum of the substrate holder up to a predetermined rotational velocity, while the inlet airlock chamber of low vacuum is pumped out to 10-20 Pa pressure;
(e) after suction and drum spinning, a first transport gate unlocks, and the substrate holder transfers to a first inlet airlock chamber of high vacuum, and the first transport gate locks;
(f) the first inlet airlock chamber of high vacuum employs turbo-molecular pumps to suck air to <
0.01 Pa pressure;
(g) after the suction of the first inlet airlock chamber of high vacuum is complete, a secondtransport gate unlocks and the substrate holder transfers to a first inlet buffer chamber, and the second transport gate locks;
(h) within the inlet buffer chamber, the substrate holder is slowed down to a process speed, and connects with another substrate holder introduced to the manufacturing line from a previous step;
(i) magnetic couplings of the substrate holders connect, and rotation of the incoming substrate holder is synchronized with the rotation of the substrate holder or holders from previous steps, all passing through process chambers;
(j) power is supplied to transportation system rollers inside the process chambers, so the electric motors of substrate holders maintain drum rotation;
(k) the coating application on the substrate holders occur inside process chambers in a processing zone where the drum rotates and moves evenly along its own axis;
(l) after passing through the processing chambers, the substrate holder enters a outlet buffer chamber;
(m) a third transport gate unlocks and the substrate holder speeds up to distance itself from a later substrate holder, moving to a second inlet airlock chamber of high vacuum;
(n) the third transport gate locks and a fourth transport gate unlocks, and the substrate holder moves to an outlet airlock chamber of low vacuum;
(o) in the outlet airlock chamber of low vacuum, a front component of a magnetic component of the substrate holder connects with a mating component of a magnetic coupling installed on a shaft of a second door of the airlock chamber, said connection slows down the substrate holder drum until it stops due to friction from the mating component;
(p) the fourth transport gate closes, desiccated air is pumped into the outlet airlock chamber of low vacuum, and pressure is raised to atmospheric; and
(q) once the pressure becomes atmospheric, the second chamber door opens and the substrate holder exits the manufacturing line.
1 Assignment
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Accused Products
Abstract
A group of inventions is related to process equipment to process surfaces in mass production, particularly, vacuum process equipment to apply thin film coatings with set optical, electrical and other parameters.
The technical result is to ensure a capability of processing flexible large substrates, as well as small substrates with a high degree of coating uniformity, with an ability to utilize a wide range of technologies and process devices, as well as to have a highly effective useful operation of applied materials.
The proposed technical result is obtained by a method of applying thin film coatings on substrates, which are placed on rotating drums, which consequently move along the processing zones with the same constant linear and angular speeds.
Furthermore, a ratio between the linear and angular speeds of the drum is selected so that each surface point of the drum will complete at least two full revolutions while passing through the processing zone.
Also, the proposed technical result is also achieved by the fact that within the manufacturing line for applying the thin film coatings, consisting of the inlet airlock chamber, process chamber with at least one process device within it, which forms a processing zone, outlet buffer chamber, transportation system and substrate holder, designed to move along chambers, a substrate holder designed as a carriage with a cylinder installed on it, positioned coaxially toward the movement direction of the carriage and designed to rotate, while the angular rotational velocity and linear speed of the movement, during the processing, will be constant and selected so that each surface point of the cylinder will complete at least two full revolutions while passing through the processing zone. Furthermore, the transportation system will be equipped with rollers, and carriage with guides that interact with rollers.
0 Citations
3 Claims
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1. A method of applying thin film coatings on substrates, consisting of substrate holders and consequent movement of substrate holders through process chambers of a manufacturing line comprising the following steps:
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(a) Fastening a substrate to a substrate holder; (b) the substrate holder enters an inlet airlock chamber of low vacuum of the manufacturing line, after which a first door of the airlock chamber closes; (c) the substrate holder retreats and a removable coupling of said substrate holder connects to a mating part of a coupling installed on a rotating shaft of the first door of the airlock chamber, said rotating shaft being driven by an electric motor installed on said first door of the airlock chamber; (d) an electric motor spins a drum of the substrate holder up to a predetermined rotational velocity, while the inlet airlock chamber of low vacuum is pumped out to 10-20 Pa pressure; (e) after suction and drum spinning, a first transport gate unlocks, and the substrate holder transfers to a first inlet airlock chamber of high vacuum, and the first transport gate locks; (f) the first inlet airlock chamber of high vacuum employs turbo-molecular pumps to suck air to <
0.01 Pa pressure;(g) after the suction of the first inlet airlock chamber of high vacuum is complete, a second transport gate unlocks and the substrate holder transfers to a first inlet buffer chamber, and the second transport gate locks; (h) within the inlet buffer chamber, the substrate holder is slowed down to a process speed, and connects with another substrate holder introduced to the manufacturing line from a previous step; (i) magnetic couplings of the substrate holders connect, and rotation of the incoming substrate holder is synchronized with the rotation of the substrate holder or holders from previous steps, all passing through process chambers; (j) power is supplied to transportation system rollers inside the process chambers, so the electric motors of substrate holders maintain drum rotation; (k) the coating application on the substrate holders occur inside process chambers in a processing zone where the drum rotates and moves evenly along its own axis; (l) after passing through the processing chambers, the substrate holder enters a outlet buffer chamber; (m) a third transport gate unlocks and the substrate holder speeds up to distance itself from a later substrate holder, moving to a second inlet airlock chamber of high vacuum; (n) the third transport gate locks and a fourth transport gate unlocks, and the substrate holder moves to an outlet airlock chamber of low vacuum; (o) in the outlet airlock chamber of low vacuum, a front component of a magnetic component of the substrate holder connects with a mating component of a magnetic coupling installed on a shaft of a second door of the airlock chamber, said connection slows down the substrate holder drum until it stops due to friction from the mating component; (p) the fourth transport gate closes, desiccated air is pumped into the outlet airlock chamber of low vacuum, and pressure is raised to atmospheric; and (q) once the pressure becomes atmospheric, the second chamber door opens and the substrate holder exits the manufacturing line. - View Dependent Claims (2, 3)
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Specification
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- Resources
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Current AssigneeThe Batteries Sp. z o.o.
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Original AssigneeThe Batteries Sp. z o.o.
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InventorsKHISAMOV, Ayrat Khamitovich
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Granted Patent
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Time in Patent OfficeDays
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Field of Search
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US Class Current
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CPC Class CodesC23C 14/24 Vacuum evaporationC23C 14/505 for rotation of the substratesC23C 14/56 Apparatus specially adapted...C23C 14/566 using a load-lock chamber
