System and a method for polishing optical connectors
A polishing system for polishing optical connectors includes at least one polishing station having a region of polishing film overlying a substrate block, and a polishing fixture (200). The polishing fixture has connector mounting holes (204) for receiving optical connectors and a working liquid supply arrangement including working liquid release channels (210) for directing working liquid to regions adjacent to the connector mounting holes. One or more of the working liquid release channels is inter-spaced between the connector mounting holes. The polishing system also includes a drive system (174) (176) (178) for generating relative motion between the polishing fixture and the polishing station so as to polish the optical connectors.
The present invention relates to the field of polishing connectors. More particularly the present invention relates to a method for polishing optical connectors and a system for implementing the method.
BACKGROUND OF THE INVENTIONWith the growth of optical communication networks there is a growing need for altering the network configuration, connecting to it new nodes and devices, disconnecting old devices and maintaining the network. These connections are easy and convenient to make with the help of an optical connector, which is a demountable device for attaching an optical fiber to another optical fiber, or to an active or passive device.
The losses of the optical signal power at each connection depend on the geometry of the connector end-face, matching surfaces geometry, surface quality and other parameters. In order to reduce optical signal power coupling losses the end-face of an optical connector typically comprising an optical fiber inserted into a ferrule is polished. The polished end-face surface may be flat, inclined or have a radius in accordance with the type of connection desired. The term “optical connector” as used herein in the description and claims denotes any polished end-face region of a fiber configured for optical connection to an adjacent element. Typically, the optical connector includes a fiber end inserted into a ferrule, although optical connectors without a ferrule (for example, certain MT type connectors) can also be polished using the systems and methods of the present invention.
Polishing of an optical connector on a piece-by-piece basis is not practical due to the nature of the process as well as the mix of the quantities and the structure of the connectors to be polished. This is the main reason why optical connectors are typically polished in batches. For polishing, a batch of optical connectors is mounted in a so-called polishing fixture. U.S. Pat. No. 5,961,374 to Minami et al. discloses some such polishing fixtures.
U.S. Pat. Nos. 5,947,797, 6,183,343, and 6,190,239 all to Buzzetti disclose a polishing fixture (
Polishing is usually conducted in the presence of a working liquid, which may be water, a specially formulated water-based solution, or any other fluid composition with suitable coolant and/or lubricant properties. For the purpose of brevity, the description of the invention below will refer to the working liquid by way of a preferred example as “water”. Nevertheless, it should be appreciated that all other working liquids fall equally within the scope of the invention as claimed. Water plays an important role in the polishing process. Water cools the part being polished, removes particles, contamination and other debris that may destroy a polished connector end-face made up of the fiber and ferrule surface. The supply rate of water is controlled to maintain proper concentration of polishing slurry, and the water provides lubrication between polished parts and polishing substrate. Water (and sometimes other fluids) is usually delivered to the polishing member and to the actual polishing area, typically to the periphery of the polishing fixture by a fluid delivery system separate from the polishing fixture. The central and other parts of the polishing area do not get a sufficient amount of water. There is no method known to the inventors of the present invention of polishing a fiber and ferrule end-face on a rotating, linearly moving, or static polishing member that ensures proper water delivery to each and every polished connector mounted on the polishing fixture.
There is no polishing fixture known to the inventors of the present invention capable of delivering the proper amount of water to each connector or each part of a plurality of parts being simultaneously polished.
In the context of present invention, “polishing member” means a part having a surface with polishing slurry, or having a rigid or a resilient surface covered by polishing film or paper, on which actual polishing takes place. The terms “polishing film”, “polishing paper”, and “polishing member” in the context of the present invention are used interchangeably unless specified otherwise.
When separate optical patch cords are polished the excessive fiber length is mounted on a hanger, which in many instances is part of a polishing fixture. Recently the use of flexible optical circuits, which represent multiple fiber bundles and cables proper routed and laminated between two polymeric substrates, has increased. Polishing of the connectors, which are terminations of the optical fiber cables and bundles forming the flexible optical circuit, is a complicate task, since it requires support of the complete flexible optical circuit. The support of the flexible optical circuit should substantially eliminate relative movement between the polished connector and the flexible optical circuit. There is no commercially available solution for polishing of such flexible optical circuits.
Polishing film is an expensive material and its condition is important for proper polishing process. Rotating polishing members typically use only a small part of the polishing surface or film. Methods of optimizing use of polishing surface or film placed on such a rotating polishing support are disclosed in U.S. Pat. No. 5,961,374 to Minami et al. Despite the various attempts described therein to optimize usage of the polishing materials, Minami et al. fails to address the fundamental drawback that polishing of the parts mounted on the polishing fixture takes place at differing speeds. Specifically, since the different parts are mounted at different distances or radiuses of the polishing disk, the rotating polishing action results in unequal polishing conditions and non-uniform wear of the polishing material.
U.S. Pat. Nos. 5,947,797; 6,183,343; 6,190,239; 6,302,763, and 6,428,391 all to Buzzetti teach polishing on a linearly moving polishing member. Movement of the stages holding the polishing material or member ensures a more uniform polishing material usage and equal polishing speed of each of the polished parts. Buzzetti's patents do not, however, teach optimization of polishing material usage.
In both cases of a rotating or linearly moving polishing member, polishing film or paper exchange requires stopping the machine, removal of the previously used film, insertion of a new film, and restarting the machine for the next polishing cycle. This procedure results in considerable time wastage during the polishing process.
Polishing machines that use polishing film in the form of a web form are known in the art. These machines allow polishing film exchange by automatic polishing film advance, thereby saving time, as compared with machines using film sheets placed over rotating or linearly moving polishing film supports. In most cases, however, machines with automated advancing of polishing film tend to be inefficient in their use of the film. Loading and tensioning of polishing material on such machines is complicate and usually is performed by a number of rollers holding the polishing material and, in some cases, rotating or moving together with the polishing material.
The polished optical connector end-face surface may be flat or have a radius in accordance with the type of connector polishing desired. Flat fiber and ferrule end-faces are obtained by polishing on a flat rigid polishing surface or member. Polishing on a polishing member having resilient polishing surface results in a fiber and ferrule end-face having a curvature. There is no method known to the inventors of the present invention for polishing a fiber and ferrule end-face on a static, non-moving polishing member that results in a fiber and ferrule end-face having a curvature.
Polishing of optical connectors and some other photonic elements may be performed using a fixed set of polishing process parameters or in accordance with a predefined set of polishing process parameters sometimes called a recipe. Development of recipes requires collection of the results of a large number of polishing cycles and statistical processing of the results collected. This complicates instant correction of the polishing process that may be required from one to the next polishing cycle. It would be desirable to have a system that has certain learning features enabling adaptation of polishing process parameters such as polishing speed, polishing time, and place on the polishing member selected in accordance with the results of the previous polishing cycle.
It would be also desirable to have an automated polishing systems incorporating in it the discussed features and providing a fully automated Photonic components set-up, polishing, cleaning and inspection cycle.
SUMMARY OF THE INVENTIONThe present invention is a polishing system for polishing optical connectors.
According to the teachings of the present invention there is provided, a polishing system for polishing optical connectors, the polishing system comprising: (a) at least one polishing station including a region of polishing film overlying a substrate block; (b) a polishing fixture having: (i) a plurality of connector mounting holes disposed across an area of the polishing fixture, each of the connector mounting holes receiving an optical connector, and (ii) a working liquid supply arrangement including a plurality of working liquid release channels for directing working liquid to regions adjacent to the connector mounting holes, at least one of the working liquid release channels being interspaced between a plurality of the connector mounting holes; and (c) a drive system for generating relative motion between the polishing fixture and the at least one polishing station so as to polish the optical connectors.
According to a further feature of the present invention, each of the connector mounting holes has a nearest neighbor spacing measured from the connector mounting hole to a nearest neighboring connector mounting hole, and wherein a spacing from each of a majority of the connector mounting holes to a nearest one of the working liquid supply channels is not more than twice an average of the nearest neighbor spacings.
According to a further feature of the present invention, a majority of the connector mounting holes are substantially equidistant from a nearest one of the working liquid supply channels.
According to a further feature of the present invention, the polishing fixture includes a mounting plate, both the connector mounting holes and the working liquid supply channels being formed as openings through the mounting plate.
According to a further feature of the present invention, the drive system is associated with the polishing fixture so as to move the polishing fixture along a two-dimensional polishing path relative to the at least one polishing station and wherein the at least one polishing station is configured to hold the region of polishing film static while the polishing fixture moves along the polishing path.
According to a further feature of the present invention, the drive system is further configured to raise the polishing fixture out of contact with the at least one polishing station on completion of a polishing operation.
According to a further feature of the present invention, the drive system is implemented as a set of three linear actuators.
According to a further feature of the present invention, there is also provided an optical cable support including at least one reel for receiving lengths of optical cables associated with the optical connectors being polished.
According to a further feature of the present invention, the cable support further includes a displacement mechanism configured to allow displacement of the reel in at least one direction.
According to a further feature of the present invention, a flexible optical circuit support rack associated with the polishing fixture for supporting a flexible optical circuit associated with the optical connectors being polished.
According to a further feature of the present invention, the flexible optical circuit support rack includes a clamping plate extending vertically above the polishing fixture, the clamping plate having a two dimensional array of bolt holes.
According to a further feature of the present invention, there is also provided a cleaning station including: (a) a wiping cloth supply roll; (b) a wiping cloth receiving roll; (c) a length of wiping cloth partially stored on the supply roll and stretched to the receiving roll to as to leave an exposed wiping cloth region; and (d) a winding actuator associated with the receiving roll and configured for actuating the receiving roll so as to bring a new portion of the length of wiping cloth into the exposed wiping cloth region.
According to a further feature of the present invention, the supply roll, the receiving roll and the length of wiping cloth are implemented as parts of a wiping cloth cassette.
According to a further feature of the present invention, there is also provided: (a) a polishing film feed mechanism for selectively exchanging the region of polishing film overlying the substrate block; and (b) a computerized controller for controlling the drive system and the feed mechanism, the controller being configured to: (i) actuate the drive system during a first polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, (ii) actuate the drive system during at least one additional polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, the polishing profiles of the additional polishing operation being interspaced with, and non-overlapping, the polishing profiles of the first polishing operation, and (iii) actuate the feed mechanism so as to advance the polishing film.
There is also provided, according to the teachings of the present invention, a polishing system for polishing optical connectors, the polishing system comprising: (a) at least one polishing station including a region of polishing film overlying a substrate block; (b) a polishing film feed mechanism for selectively exchanging the region of polishing film overlying the substrate block; (c) a polishing fixture having a plurality of connector mounting holes disposed across an area of the polishing fixture, each of the connector mounting holes receiving an optical connector; (d) a drive system for generating relative motion between the polishing fixture and the at least one polishing station so as to polish the optical connectors; and (e) a computerized controller for controlling the drive system and the feed mechanism, the controller being configured to: (i) actuate the drive system during a first polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, (ii) actuate the drive system during at least one additional polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, the polishing profiles of the additional polishing operation being interspaced with, and non-overlapping, the polishing profiles of the first polishing operation, and (iii) actuate the feed mechanism so as to advance the polishing film.
There is also provided, according to the teachings of the present invention, a polishing system for polishing optical connectors, the polishing system comprising a cleaning station having: (a) wiping cloth cassette including: (i) a wiping cloth supply roll, (ii) a wiping cloth receiving roll, and (iii) a length of wiping cloth partially stored on the supply roll and stretched to the receiving roll to as to leave an exposed wiping cloth region; and (b) a winding actuator associated with the receiving roll and configured for actuating the receiving roll so as to bring a new portion of the length of wiping cloth into the exposed wiping cloth region.
There is also provided, according to the teachings of the present invention, a method for polishing optical connectors of a flexible optical circuit, the method comprising: (a) providing a polishing fixture including: (i) a plurality of connector mounting holes disposed across an area of the polishing fixture, each of the connector mounting holes receiving an optical connector, and (ii) a support rack for supporting a flexible optical circuit; (b) mounting a flexible optical circuit with a plurality of optical connectors mounted in the connector mounting holes and with at least part of a body of the flexible optical circuit attached to the support rack; and (c) generating relative motion between the polishing fixture and a polishing surface.
According to a further feature of the present invention, the relative motion is generated by a drive system associated with the polishing system, the polishing surface remaining static at least during a given polishing operation.
There is also provided, according to the teachings of the present invention, a method of polishing of the leading end face portion of a plurality of batches of optical connectors having a foremost end having a ferrule integrated with optical fiber, comprising steps of: (a) mounting first batch of optical connectors in a polishing fixture having a plurality of optical connectors mounting holes at a predetermined inclination angle and a plurality of working liquid delivery openings interspaced with the optical connectors mounting holes; (b) bringing the leading end faces of the mounted in the polishing fixture first batch optical connectors into forced contact with a static polishing member; (c) sliding the polishing fixture with the first batch of optical connectors simultaneously in two independent and orthogonal directions on the polishing member; (d) supplying through a plurality of openings and channels in the polishing fixture a working liquid to a plurality of optical connectors being polished and to the polishing member; (e) polishing the surface of the leading end face portion of the first batch of optical connectors by the sliding movement in a brushing pattern generated by independent changes of the sliding movement speed in each of the two orthogonal polishing fixture movement directions; and (f) controlling all of the polishing and auxiliary processes by a computer, the computer monitoring and memorizing all of the processes steps and parameters, wherein at least one of the polishing process parameters for polishing the surface of the leading end face portion of at least one of the following optical connector batches is changed by the computer, based on the results of previously polished optical connectors batch.
BRIEF DESCRIPTION OF THE DRAWINGSThe invention is herein described, by way of non-limiting example only, with reference to the accompanying drawings, wherein:
The principles and execution of a method according to the present invention, and the operation and properties of a polishing system described thereby may be understood with reference to the drawings and the accompanying description of non-limiting, exemplary embodiments.
By way of general introduction, before addressing the drawings in detail, it should be appreciated that certain preferred implementations of the present invention provide a polishing system comprising a set-up station for proper position and mounting of a plurality of optical connectors to be polished and a polishing station. The polishing station optionally and preferably may include in addition to a polishing sub-system, a cleaning sub-system, a rinsing and drying sub-system, an inspection subsystem, and a control computer controlling the operation of all sub-systems and stations comprising the polishing system.
In accordance with one exemplary embodiment of the present invention the object of providing a method of polishing optical connectors or other photonic elements in which each of the optical connectors or other photonic elements being polished gets equal and sufficient amount of water may be achieved by providing an optical connector polishing system for polishing optical connectors including a polishing fixture having a plurality of optical connectors mounting holes. The optical connectors mounting holes optionally and preferably are distributed across the area of the polishing fixture and not only along the perimeter of the polishing fixture. Mounting a plurality of optical connectors to be polished in the mounting holes of the polishing fixture, polishing the plurality of connectors mounted in the mounting holes of the polishing fixture and delivering water to each of the plurality of optical connectors being polished through the water delivery openings placed in the spaces between said plurality of optical connectors mounting holes.
In accordance with another exemplary embodiment of the present invention the object of providing a method of simultaneous polishing of a large number of optical connectors and other photonic elements in which the polishing speed of each optical connector and other photonic elements is equal may be achieved by mounting a plurality of optical connectors in a polishing fixture and polishing them on a flat static polishing member. The polishing fixture may optionally and preferably have a plurality of optical connectors mounting holes distributed across the surface of the polishing fixture and not only along the perimeter of the polishing fixture. Optionally but not necessary the mounting holes of the polishing fixture may be located on a grid.
The leading portion of an optical connector end-face may be polished to a flat surface by polishing it on a rigid flat static surface, In accordance with yet another exemplary embodiment of the present invention the leading portion of the optical connector end-face may be polished into a curved surface by said sliding movement in at least two orthogonal directions. The polishing member in this case is optionally and preferably a resilient, web-polishing member. The resilient web-polishing member is static in process of polishing.
A polishing fixture sliding mechanism capable of sliding said polishing fixture simultaneously in at least two orthogonal directions on the static polishing member provides all required for polishing fixture movements. The sliding mechanism optionally and preferably slides the polishing fixture simultaneously in at least two orthogonal directions and the sliding speed in the first direction is independent and optionally and preferably different of the sliding speed in the second direction, and the sliding movement of the polishing fixture is a sum of the first and second independent movements. The polishing fixture sliding mechanism is further capable of applying a controlled force to said polishing fixture and measuring the advance or descent speed of the polishing fixture.
Economic polishing film usage in accordance with the present invention is achieved by positioning the polishing fixture holding a plurality of optical connectors to be polished on a first section of a static polishing member. Polishing the first plurality of optical connectors by operating said polishing fixture sliding mechanism capable of sliding said polishing fixture simultaneously in at least two orthogonal directions on the first section of static polishing member. Positioning the polishing fixture holding the next plurality of to be polished optical connectors on a second section of a static polishing member, where the second section is different from the first section and optionally and preferably does not overlap the first section. Polishing the second plurality of optical connectors by operating said polishing fixture sliding mechanism capable of sliding said polishing fixture simultaneously in at least two orthogonal directions on the second section of static polishing member.
In accordance with an additional exemplary embodiment of the present invention, a control computer controls the process of positioning the polishing fixture on the first section of the static polishing member and optionally and preferably records the coordinates of the first section or polishing area. The control computer calculates the coordinates of the second section or polishing area of the static polishing member and optionally and preferably positions on it the polishing fixture for the next polishing cycle. Control computer takes care that the second polishing area preferably does not overlap with the first polishing area. The polishing fixture sliding mechanism performs both the operational or polishing movement holding the polishing fixture with a plurality of optical connectors over the first section of the polishing member and the auxiliary movement of repositioning the polishing fixture next plurality of to be polished to the second section of a static polishing member.
The present invention provides a method of easy web polishing material exchange that does not require any special operator skills and maintains the same polishing film tension and adhesion to the underlying polishing member surface. In accordance with this method, the polishing film is provided in a polishing film supply cassette for supply and tensioning the polishing film.
According to one of the embodiments, the polishing film supply and tensioning cassette or roll is preferably a disposable cassette and comprises a hollow cylindrical core having first and second end with the polishing film wind on the hollow cylindrical core. The hollow cylindrical core with the film rotates on a shaft. Friction between the hollow cylindrical core and a pair of expandable cylindrical inserts holds the hollow cylindrical core on the shaft. The expandable cylindrical inserts change the force, and accordingly the torque, they apply to the hollow cylindrical core as a function of the pressure applied to them by outer tapered cylinders inserted at both ends of the hollow core and inner tapered cylinders. A flexible element, such as a spring inserted between the inner tapered cylinders generates the pressure. Both outer and inner tapered cylinders are movably coupled with a common shaft. One of external tapered cylinders is rigidly coupled with the shaft. Second external tapered cylinder can slide on the shaft, although it can be fixed in any sliding position and become rigidly coupled with the shaft. Inner tapered cylinders can slide on shaft, but preferably rotate with it. The tension of unwind film is regulated by the force required to overcome the pressure generated by the flexible element.
According to the present invention, the polishing film dispensed from the supply roll or cassette is tensioned and adhered to a polishing unit, comprising a rigid frame having a flat surface, and an elastic or rigid member, placed in a trough in the flat surface. The polishing film is supplied by a polishing film supply roll or cassette and is disposed on the elastic or rigid member surface of the polishing unit. The receiving cassette or roll is capable of incrementally unwinding and advancing the polishing film. Polishing film is advanced between the polishing cycles and remains static in the course of the polishing process. Water ensures polishing film adhesion to the resilient or rigid insert of the polishing member. The force required to advance the polishing film regulates polishing film tension and provides additional polishing film adhesion force. The force is a function of the pressure developed by flexible element.
According to another exemplary embodiment, the polishing film cassette is preferably a disposable cassette containing in a common package both film supply roll and film receiving roll. The polishing film is tensioned in the cassette and the force required to advance the polishing film regulates polishing film tension. Exchange of the cassette causes simultaneous change of both film supply roll and film receiving roll.
According to yet another exemplary embodiment, the wiping cloth may be packaged in a cassette, which is preferably a disposable cassette containing in a common package both wiping cloth supply roll and wiping cloth receiving roll. The wiping cloth is tensioned in the cassette and the force required to advance the wiping cloth regulates wiping cloth tension. Exchange of the cassette causes simultaneous change of both wiping cloth supply roll and wiping cloth-receiving roll.
According to another exemplary embodiment of the present invention control computer optionally and preferably monitors and stores in the memory the polishing speed, polishing fixture descent speed, number of polishing cycles made on the same polishing area, amplitude, and speed of orbital or brushing movement, and results of polished parts inspection. Based on the previous polishing cycle parameters and results control computer calculates and provides at least one parameter for the next polishing cycle. Such polishing process parameter may be polishing speed, polishing time, force applied to the polishing fixture, place on the polishing member and others.
The methods as described above provide advantages over the prior art in that the polishing of the end faces of a plurality of optical connectors is done in identical polishing conditions. Adequate water supply to each polished connector prevents polished surface degradation by contamination due to polishing residuals, reduces potential of surface scratches, and maintains constant the polished parts temperature. Ample supply of water washes out polishing residuals and promotes faster conditioning of the polishing film or polishing member. Freedom from such contaminations and polishing residuals increases the yield of optical connectors polished according to the present invention.
In addition, the present invention offers another advantage in providing all movements required for proper polishing by only two simultaneous sliding movements of the polishing fixture. The resulting movement of the polishing fixture over the static polishing member is a sum of these two independent sliding movements. By controlling the amplitude and phase of each of the independent movements, it is possible to generate any brushing or orbital movement trajectories of the polishing fixture. This makes the polishing sub-system architecture simple and the polishing machine less expensive. There is no need for complicate eccentric mechanical arrangements or pulleys supporting a limited amount of orbital movements and requiring additional sources of rotational or linear movement.
A further advantage of the present invention is that one polishing fixture sliding mechanism performs both the operational or polishing movement of sliding the fixture over a polishing area and the auxiliary movement of repositioning the polishing fixture over another section of a static polishing member.
An additional advantage of the invention is that the polishing member or film is static in the course of the polishing process. This simplifies the polishing film to the polishing unit surface or insert surface adhesion. A polishing film supply cassette that keeps the polishing film tension constant supplies the polishing film. A polishing film receiving cassette advances in case of need the polishing film in the intervals between two polishing cycles. The loading of the polishing film supply cassette is simple and does not require special operator skills. The polishing film tension is constant throughout the polishing process and contributes to the consistency of polishing results.
A further advantage provided by the method of the present invention is in the economic use of polishing material mounted on a static polishing member. The economic use of the polishing material is achieved by the lay out of optical connectors in the polishing fixture and by making each next polishing cycle on a new section or area of the polishing member not overlapping with the previously used section or area of the polishing member. The control computer keeps track of polishing material sections or areas used for polishing in previous polishing cycles and selects for the next polishing cycle new sections or areas of the polishing member that do not overlap with the previously used polishing member sections or areas.
The present invention also supports consistency of the polishing process by introducing corrections based on the results of the previous polishing cycle in the next polishing cycle polishing parameters. Such polishing parameters may be polishing speed, polishing time and others, as may be required by the particular polishing process.
Turning now more specifically to the Figures,
Control computer 106 may control polishing station 102, preparation station 104, and optional robotic arm 110. Computer 106 may control all inspection processes, perform statistical process analysis, keep process and parts databases, and issue different reports. Additionally, control computer 106 may contain programs enabling process learning. The learning capabilities support continuous polishing process improvement. They may identify process degradation parameters, for example a worn-out abrasive, and may indicate reasons for said process degradation, which require some on-line compensation, for example, adding more time to a certain step.
An operator stand 108 with monitor and Graphic User Interface (GUI) allows interactive operator intervention into each stage of the process. Control computer 106 uses a monitor with Graphic User Interface to display process status, and provide the operator with other useful information and images of the work-pieces being processed. An optional robotic arm 110 for transfer of work pieces between preparation station and polishing station may also be included into the automated optical connectors polishing system 100.
The following description provides detailed information on some of the main components of an integrated, automated optical connectors polishing system of the present invention.
Polishing fixture 200 with a plurality of optical connectors (not shown) is attached by means of bayonet type pins 250 (See
Some of the sub-systems of the polishing station and relevant to the invention will be explained now in detail.
With regard to the spacing of water delivery channels or openings 210, it is a particularly preferred feature of one aspect of the present invention that the water delivery openings are interspaced between connector mounting holes 204. Preferably, a spacing from most or all of connector mounting holes 204 to a nearest one of the water supply channels 210 is not more than twice an average of the nearest neighbor spacings of the mounting holes themselves. Most preferably, most or all of the connector mounting holes 204 are substantially equidistant from the nearest water supply channel 210. Water delivery holes 210 may be randomly spaced/positioned on the polishing fixture or arbitrarily positioned according to any desired pattern, although the polishing results in some instances may be inferior for unevenly spaced holes compared to a substantially evenly spaced arrangement of working liquid delivery holes.
Parenthetically, it should be noted that, although described herein in the context of a preferred embodiment in which a polishing fixture moves across a static polishing station, the interspaced working fluid delivery channel feature of the present invention is also applicable to other configurations such as where a circular fixture is brought into contact with a rotating polishing disk.
Excess length of standard length fiber optics cables and patch cords is located during the preparation and polishing process on a hanger 268. Hanger 268 has protruding ends 270 that prevent slippage of fiber optics bundles in the course of the polishing process. This type of handling of the excess length of the fibers is suited for relatively short fibers such as standard 3 feet, 4 feet, and 6 feet length fiber optics cables and patch cords. In an ever growing proportion of cases, optical circuitry with much longer non-standard fiber length cable and flexible optical circuitry are used, ranging from 30 feet up to thousands of feet. These cases present more complicated handling requirements. An example of a support arrangement for mounting devices of these types will now be described with reference to
Polishing of such optical connectors incorporated in a flexible optical circuit board is complicated since the board should be supported during the process and preferably there should be minimal relative motion between polished connector 406 and board 400. Relative motion between polished connector 406 and flexible board 400 weakens the fiber to connector connection point and may result in a broken fiber or introduction of cracks into the fiber. Connectors coming out of flexible boards are not necessary equally spaced, fiber cable or bundles may have different lengths, and types of connectors connected to these fiber cables may be different.
Use of a polishing fixture having a plurality of connectors mounting holes spread across the surface of the fixture enables easier connectors positioning in the mounting holes than fixtures having the connectors mounting holes distributed along the perimeter of the fixture.
Before the polishing process takes place, flexible optical circuitry 400 is mounted on polygonal prismatic mounting structure 420 and fastened to it. Fiber optics connectors 406 are inserted in mounting holes 204 of fixture 200.
Top surface 288 of each polishing unit 156 has a set of rulers 290 forming a trough in which, in accordance with the polishing process desired, a resilient material, such as rubber insert 292 or a rigid material insert 296, such as for example a glass or aluminum insert or pad may optionally be placed. When the end-face of optical connector has to be polished to a spherical shape, a rubber insert 292 or an insert of other suitable resilient material such as polyurethane is placed in the trough. In case where the end-face of optical connector has to be polished to flat shape a rigid insert 296 is placed in the trough.
A cross section of an exemplary embodiment of a polishing unit 156 of the present invention is shown in
Polishing-film receiving cassette or roll 284 (
Operation of an exemplary embodiment of polishing film dispensing or supply cassette 282 will be explained in detail now. In accordance with the present invention, polishing-film supply cassette 282, illustrated in
Polishing-film supply roll or cassette 282 comprises a hollow cylindrical core 330, having first 332 and second 334 end with polishing film 286 (shown here cut away) wound on hollow cylindrical core 330. Friction between hollow cylindrical core 330 and expandable cylindrical inserts 338 and 340 holds hollow cylindrical core 330 on a shaft 336. External tapered cylinders 344 and 346 inserted at both ends of the hollow core press expandable cylindrical inserts 338 and 340 against inner tapered cylinders 348 and 350. One of external tapered cylinders for example 346 is rigidly coupled with shaft 336. Second external tapered cylinder for example 344 can slide on shaft 336, although it can be fixed in any sliding position and become rigidly coupled with shaft 336. Inner tapered cylinders 348 and 350 can slide on shaft 336. A flexible element, such as a spring 354 applies counter pressure tensioning inner tapered cylinders against outer tapered cylinders.
Polishing-film supply roll or cassette 282 is optionally and preferably a disposable cassette. Cassette manufacturer regulates the preload generated by flexible element 354. This ensures a constant and equal value for each cassette and accordingly constant and repeatable film tension values.
In another exemplary embodiment of the present invention shown in
In yet another exemplary embodiment of the present invention shown in
Polishing fixture-sliding mechanism includes X and Y-axis drives 174 and 176 (
In accordance with an additional exemplary embodiment of the present invention, control computer 106 (
Digitally generated and controlled orbital movement combined with a static polishing member provides a number of options and benefits that existing conventional rotating disk polishing mechanical systems do not support. Change of orbital polishing pattern movement is one of them in addition to this variable speed within the same orbital movement pattern is possible. The flexibility of movement patterns combined with better speed control provides a higher polished surface quality.
Digital control of the speed of orbital movement pattern facilitates better polishing speed control. The parallel motion is also advantageous, equalizing the polishing speed of different optical connectors mounted on polishing fixture 200 and polished on a static polishing member.
While the exemplary embodiments of the present invention have been illustrated and described, it will be appreciated that various changes can be made therein without affecting the spirit and scope of the invention.
Claims
1. A polishing system for polishing optical connectors, the polishing system comprising:
- (a) at least one polishing station including a region of polishing film overlying a substrate block;
- (b) a polishing fixture having: (i) a plurality of connector mounting holes disposed across an area of said polishing fixture, each of said connector mounting holes receiving an optical connector, and (ii) a working liquid supply arrangement including a plurality of working liquid release channels for directing working liquid to regions adjacent to said connector mounting holes, at least one of said working liquid release channels being interspaced between a plurality of said connector mounting holes; and
- (c) a drive system for generating relative motion between said polishing fixture and said at least one polishing station so as to polish the optical connectors.
2. The polishing system of claim 1, wherein each of said connector mounting holes has a nearest neighbor spacing measured from said connector mounting hole to a nearest neighboring connector mounting hole, and wherein a spacing from each of a majority of said connector mounting holes to a nearest one of said working liquid supply channels is not more than twice an average of said nearest neighbor spacings.
3. The polishing system of claim 1, wherein a majority of said connector mounting holes are substantially equidistant from a nearest one of said working liquid supply channels.
4. The polishing system of claim 1, wherein said polishing fixture includes a mounting plate, both said connector mounting holes and said working liquid supply channels being formed as openings through said mounting plate.
5. The polishing system of claim 1, wherein said drive system is associated with said polishing fixture so as to move said polishing fixture along a two-dimensional polishing path relative to said at least one polishing station and wherein said at least one polishing station is configured to hold said region of polishing film static while said polishing fixture moves along said polishing path.
6. The polishing system of claim 5, wherein said drive system is further configured to raise said polishing fixture out of contact with said at least one polishing station on completion of a polishing operation.
7. The polishing system of claim 6, wherein said drive system is implemented as a set of three linear actuators.
8. The polishing system of claim 1, further comprising an optical cable support including at least one reel for receiving lengths of optical cables associated with the optical connectors being polished.
9. The polishing system of claim 8, wherein said cable support further includes a displacement mechanism configured to allow displacement of said reel in at least one direction.
10. The polishing system of claim 1, further comprising a flexible optical circuit support rack associated with said polishing fixture for supporting a flexible optical circuit associated with the optical connectors being polished.
11. The polishing system of claim 10, wherein said flexible optical circuit support rack includes a clamping plate extending vertically above said polishing fixture, said clamping plate having a two dimensional array of bolt holes.
12. The polishing system of claim 1, further comprising a cleaning station including:
- (a) a wiping cloth supply roll;
- (b) a wiping cloth receiving roll;
- (c) a length of wiping cloth partially stored on said supply roll and stretched to said receiving roll to as to leave an exposed wiping cloth region; and
- (d) a winding actuator associated with said receiving roll and configured for actuating said receiving roll so as to bring a new portion of said length of wiping cloth into said exposed wiping cloth region.
13. The polishing system of claim 12, wherein said supply roll, said receiving roll and said length of wiping cloth are implemented as parts of a wiping cloth cassette.
14. The polishing system of claim 1, further comprising:
- (a) a polishing film feed mechanism for selectively exchanging said region of polishing film overlying said substrate block; and
- (b) a computerized controller for controlling said drive system and said feed mechanism, said controller being configured to: (i) actuate said drive system during a first polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, (ii) actuate said drive system during at least one additional polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, said polishing profiles of said additional polishing operation being interspaced with, and non-overlapping, said polishing profiles of said first polishing operation, and (iii) actuate said feed mechanism so as to advance said polishing film.
15. A polishing system for polishing optical connectors, the polishing system comprising:
- (a) at least one polishing station including a region of polishing film overlying a substrate block;
- (b) a polishing film feed mechanism for selectively exchanging said region of polishing film overlying said substrate block;
- (c) a polishing fixture having a plurality of connector mounting holes disposed across an area of said polishing fixture, each of said connector mounting holes receiving an optical connector;
- (d) a drive system for generating relative motion between said polishing fixture and said at least one polishing station so as to polish the optical connectors; and
- (e) a computerized controller for controlling said drive system and said feed mechanism, said controller being configured to: (i) actuate said drive system during a first polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, (ii) actuate said drive system during at least one additional polishing operation so as to move a batch of optical connectors in a polishing motion along a corresponding set of polishing profiles in contact with the static polishing film, said polishing profiles of said additional polishing operation being interspaced with, and non-overlapping, said polishing profiles of said first polishing operation, and (iii) actuate said feed mechanism so as to advance said polishing film.
16. A polishing system for polishing optical connectors, the polishing system comprising a cleaning station having:
- (a) wiping cloth cassette including: (i) a wiping cloth supply roll, (ii) a wiping cloth receiving roll, and (iii) a length of wiping cloth partially stored on said supply roll and stretched to said receiving roll to as to leave an exposed wiping cloth region; and
- (b) a winding actuator associated with said receiving roll and configured for actuating said receiving roll so as to bring a new portion of said length of wiping cloth into said exposed wiping cloth region.
17. A method for polishing optical connectors of a flexible optical circuit, the method comprising:
- (a) providing a polishing fixture including: (i) a plurality of connector mounting holes disposed across an area of said polishing fixture, each of said connector mounting holes receiving an optical connector, and (ii) a support rack for supporting a flexible optical circuit;
- (b) mounting a flexible optical circuit with a plurality of optical connectors mounted in the connector mounting holes and with at least part of a body of the flexible optical circuit attached to the support rack; and
- (c) generating relative motion between the polishing fixture and a polishing surface.
18. The method of claim 17, wherein said relative motion is generated by a drive system associated with the polishing system, the polishing surface remaining static at least during a given polishing operation.
19. A method of polishing of the leading end face portion of a plurality of batches of optical connectors having a foremost end having a ferrule integrated with optical fiber, comprising steps of:
- (a) mounting first batch of optical connectors in a polishing fixture having a plurality of optical connectors mounting holes at a predetermined inclination angle and a plurality of working liquid delivery openings interspaced with said optical connectors mounting holes;
- (b) bringing said leading end faces of said mounted in the polishing fixture first batch optical connectors into forced contact with a static polishing member;
- (c) sliding said polishing fixture with the first batch of optical connectors simultaneously in two independent and orthogonal directions on said polishing member;
- (d) supplying through a plurality of openings and channels in said polishing fixture a working liquid to a plurality of optical connectors being polished and to said polishing member;
- (e) polishing the surface of the leading end face portion of the first batch of optical connectors by said sliding movement in a brushing pattern generated by independent changes of said sliding movement speed in each of said two orthogonal polishing fixture movement directions; and
- (f) controlling all of the polishing and auxiliary processes by a computer, said computer monitoring and memorizing all of the processes steps and parameters,
- wherein at least one of the polishing process parameters for polishing the surface of the leading end face portion of at least one of the following optical connector batches is changed by said computer, based on the results of previously polished optical connectors batch.
Type: Application
Filed: Oct 21, 2003
Publication Date: Feb 16, 2006
Inventors: Ori Sarfati (Harav Kook), Itzhak Ronen (Nirit), Rami Gazit (Beit Shaen)
Application Number: 10/537,658
International Classification: B24B 51/00 (20060101); B24B 49/00 (20060101);