This application claims the priority benefits of Taiwan application serial No. 105123392, filed on Jul. 25, 2016, the entirety of which is incorporated by reference herein.
The disclosure relates to a roller with pressure sensor and a roll-to-roll device.
A roll-to-roll device could adopt a process of controlling a reel by the gravitational force to alleviate the non-uniform tension. In addition to detection of variation of tension, the roll-to-roll device still requires to monitor and regulate the detection of speed variation, during a process of transferring a film. Under a normal operation, when an automatic unwinding and tension monitoring module is activated, it cooperates with a winding module at the rear end for performing a transfer process. In the transfer process, regulating the non-uniform tension could be performed because of the difference of speed control between the front and the rear ends. When a steady state for the regulating is reached, the entire line for the transfer process can perform the transferring synchronously. For transferring an ultrathin glass substrate, sensors that are arranged in a load cell under a roller can be used to detect tension and speed so as to identify if a breaking or a cracking occurs in the substrate during the transfer process.
A conventional roll-to-roll device comprises a winding/unwinding mechanism, a buffering mechanism, a cushioning mechanism, an edge-following positioning mechanism, and a full-hood high-efficiency particulate air (HEPA) filter unit. The winding/unwinding mechanism uses a servomotor in cooperation with the load cell, to control the tension of the material roll. The buffering mechanism keeps manufacturing by a way of non-stop. The cushioning mechanism peels a film of a substrate and can be used, flexibly, in various production processes. The edge-following positioning mechanism involves an edge position control (E.P.C.) system to achieve neat and regular winding. The full-hood HEPA filter unit helps to maximize purity and cleanness.
The disclosure provides an embodiment of a roller with pressure sensor, wherein a pressure sensor is attached to the roller and the pressure sensor comprises a plurality of pressure sensing units distributed on a thin film such that the pressure sensing units are electrically connected but not in contact with each other.
The disclosure provides an embodiment of a roll-to-roll device, which at least comprises a roller mechanism, the roller mechanism comprising an unwinding roller, a first intermediate roller, a second intermediate roller, a third intermediate roller, and a winding roller; and a pressure sensor being mounted to each of the first intermediate roller, the second intermediate roller, and the third intermediate roller.
The disclosure provides another embodiment of the roll-to-roll device. In the embodiment, the roll roll-to-roll device comprises a chassis, which comprises a longitudinal chassis and a transverse chassis; an unwinding unit; a plurality of intermediate rollers, which comprises a first upper intermediate roller, a first lower intermediate roller, a second upper intermediate roller, a second lower intermediate roller, and a third upper intermediate roller; and a winding unit, wherein the unwinding unit, a front dual-clamping roller, the plurality of intermediate rollers, a rear dual-clamping roller, and a winding unit are mounted on the chassis such that the first upper intermediate roller, the second upper intermediate roller, and the third upper intermediate roller are mounted to the transverse chassis, and the first lower intermediate roller and the second lower intermediate roller are mounted to the longitudinal chassis; wherein the unwinding unit and the winding unit are respectively arranged on a front side and a rear side of the chassis, the front dual-clamping roller is arranged between the unwinding unit and the first upper intermediate roller, and the rear dual-clamping roller is arranged between the winding unit and the third upper intermediate roller; and wherein the unwinding unit forwards a thin substrate unwound from a material roll through a front dual-clamping roller, allowing the thin substrate to pass through the first upper intermediate roller, and then pass through the first lower intermediate roller, the second upper intermediate roller, the second lower intermediate roller, and the third upper intermediate roller, and then the thin substrate is sent out by the rear dual-clamping roller for being wound by the winding device.
The foregoing will become better understood from a careful reading of a detailed description provided herein below with appropriate reference to the accompanying drawings.
Below, exemplary embodiments will be described in detail with reference to accompanying drawings to be easily realized by a person having ordinary knowledge in the art. The inventive concept may be embodied in various forms without being limited to the exemplary embodiments set forth herein. Descriptions of well-known parts are omitted for clarity, and like reference numerals refer to like elements throughout.
Referring to
In another embodiment, the pressure sensor 10 may be alternatively arranged as a plurality of strip-shaped pressure sensors circumferentially arranged on the surface 22 of the roller 20.
In an embodiment, the roller 20 may be of a hollow structure or a non-hollow structure. Thus, the pressure sensor 10 may be mounted to an internal wall of the roller 20 at a location close to the surface 22 of the roller 20 in order to conduct a detection in a range engageable with a thin substrate 30. Thus, with such an arrangement, sensitivity of the detection of the pressure sensor 10 may be ensured.
In an embodiment, the plurality of pressure sensing units 12 of the pressure sensor 10 may be arranged in an array and are electrically connected to each other by means of for example metal wires. And, a micro integrated circuit (IC) and a signal transmitter are arranged at an end of the pressure sensor 10, as shown in
Referring to
In an embodiment, the vibration membrane 14 of the disclosure may be a piezoelectric sensor or a resistive pressure sensor, or a capacitive pressure sensor; however, the scope of the disclosure is not limited thereto.
In an embodiment, the vibration membrane 14 has a piezoelectric coefficient D33, which, for ceramics, is 500 pico-coulomb/newton (PC/N, 10−9 coulomb/newton) and, for polyvinylidene fluoride (PVDF), is 18-32 PC/N.
Referring to
Referring to
A tightness problem of the thin substrate 30 may cause abnormality of transferring the thin substrate 30 and abnormal winding of the roller 20. Thus, in an embodiment, when the pressure sensing units 12 are affected by over-tightness or under-tightness of the thin substrate 30, an abnormality signal is issued to indicate there is a tightness problem occurring in the thin substrate 30 and it is needed to adjust a spacing distance between two rollers 20. Details will be provided below.
In an embodiment, it may be arranged to completely wrap the pressure sensor 10 around the roller 20, so that when the thin substrate 30 is moved on the roller 20, the voltage distribution on the thin substrate 30 can be detected, thereby to identifying the pressure distribution on the thin substrate 30. Therefore, a voltage signal is transmitted to the controller 40 for controlling a motor to adjust the rollers 20 to uniformly transfer the thin substrate 30. Also, knowing the pressure of the rollers 20 may adjust the rollers 20 of each manufacturing line such that an entire manufacturing can be conducted in a smooth, accurate, and efficient manner.
Accordingly, the embodiments of the disclosure may detect the pressure distribution, while the known pressure sensors using load cell do not detect the pressure distribution. Thus, the embodiments of the disclosure help to improve a transfer efficiency of a thin substrate and allow for continuously monitoring and detecting the transfer process of the thin substrate.
Referring to
In an embodiment, the roll-to-roll device of the disclosure may further comprise a cushioning mechanism, a buffering mechanism, an edge-following positioning mechanism, and a full-hood HEPA filter unit (not shown in the drawings). Details will not be provided herein.
Referring to
Referring to
In an embodiment, in case that a problem of for example the tightness of the thin substrate 30 or the speed of the roller 20 occurs, then improvement may be made by adjusting the spacing distance or the speed of the roller 20.
In an embodiment, in case that the tension of the thin substrate 30 is not uniform, the location of the thin substrate is incorrect, or there are dust particles, then the device must be shut down for adjusting and improving the factors.
Referring to
A roller mechanism 60 comprises an unwinding roller 62, an intermediate roller 64, and a winding roller 66. The pressure sensor 10 is mounted to the intermediate roller 64. The thin substrate 30 is unwound and released from the unwinding roller 62, and after passing through the intermediate roller 64, the thin substrate 30 is wound up by the winding roller 66. Thus, when a problem of the tightness of the thin substrate 30 or the speed of the roller 20 occurs, through an operation of motors 68 to adjust the spacing distance between the unwinding roller 62 and the winding roller 66 or to adjust the speed of the unwinding roller 62 or the winding roller 66, the problem of the tightness of the thin substrate 30 or the speed of the roller can be overcome. The motors 68 are respectively controlled by signals issued from the controller 40.
Referring to
In an embodiment, the front dual-clamping roller 721, the first upper intermediate roller 731, the first lower intermediate roller 732, the second upper intermediate roller 733, the second lower intermediate roller 734, the third upper intermediate roller 735, and the rear dual-clamping roller 741 may be controlled by motors to control the spacing distance or the location of the roller 20 in order to adjust the tension and the level of tightness of the thin substrate 30.
In an exemplary embodiment, if desired, the exemplary embodiment of the disclosure may be structured to provide a pressure sensor 10 on any one or all of the front dual-clamping roller 721, the first upper intermediate roller 731, the first lower intermediate roller 732, the second upper intermediate roller 733, the second lower intermediate roller 734, the third upper intermediate roller 735, and the rear dual-clamping roller 741 or on a part of the roller 20 in order to timely detect abnormality of the thin substrate 30 positioned on the roller 20.
The disclosure is to provide a roller with pressure sensor and a roll-to-roll device, wherein a pressure sensor is arranged to completely wrap around a roller, so that when a thin substrate is moved on the roller, the voltage distribution of the thin substrate may be detected to identify distribution of pressure and such a voltage signal is transmitted to a controller to control a motor to adjust the roller so as to make the transferring of the thin substrate smooth and allowing to identify the pressure on the roller for adjusting rollers of each manufacturing line and making the manufacturing smooth, accurate, and efficient.
The disclosure is to provide a roller with pressure sensor and a roll-to-roll device, which may detect the distribution of pressure on a thin substrate. Compared with a known way of adopting a load cell comprising a pressure sensor that cannot detect the distribution of pressure, the embodiments of the disclosure allow for effective improvement of the transfer efficiency of the thin substrate and allow for continuously monitoring and detecting the transfer process of the thin substrate.
In summary, the embodiments of the disclosure provides a pressure sensor on a roller, which comprises for example a sheet like arrangement of an array of pressure sensing units to detect if the distribution of pressure on a thin substrate is uniform in order to improve the transfer efficiency of the thin substrate and to continuously monitor and detect the transfer process of the thin substrate. Further, with the thin substrate being moved on the roller, the voltage distribution of the thin substrate may be detected to identify the distribution of pressure. Such a voltage signal may be transmitted to a controller for controlling motors to adjust the roller. This makes the transfer of the thin substrate uniform and allows to know the roller pressure for adjusting rollers of each manufacturing line to make an entire manufacturing smooth, accurate, and efficient.
It will be apparent to those skilled in the art that various modifications and variations can be made to the disclosure. It is intended that the specification and examples be considered as exemplary embodiments only, with a scope of the disclosure being indicated by the following claims and their equivalents.
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105123392 A | Jul 2016 | TW | national |
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Entry |
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Taiwan Patent Office, Office Action, Patent Application Serial No. 105123392, dated Oct. 6. 2017, Taiwan. |
Number | Date | Country | |
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20180022563 A1 | Jan 2018 | US |