Media processing devices configured to process discrete media units, such as card printers configured to print identity cards, may be required to accommodate various methods of media unit supply, while consistently dispensing media units from the supply for processing. Such requirements can lead to increased complexity and cost of the media processing devices.
The accompanying figures, where like reference numerals refer to identical or functionally similar elements throughout the separate views, together with the detailed description below, are incorporated in and form part of the specification, and serve to further illustrate embodiments of concepts that include the claimed invention, and explain various principles and advantages of those embodiments.
Skilled artisans will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of embodiments of the present disclosure.
The apparatus and method components have been represented where appropriate by conventional symbols in the drawings, showing only those specific details that are pertinent to understanding embodiments of the apparatus and methods disclosed herein so as not to obscure the disclosure with details that will be readily apparent to those of ordinary skill in the art having the benefit of the description herein.
Some media processing devices are configured to process discrete media units, such as identity cards (e.g., driver's licenses or employee badges). Some examples disclosed herein are described using the term “cards.” However, cards are example discrete media units and example methods and apparatus disclosed herein are applicable to any suitable type of discrete media unit(s).
Media processing devices configured to process discrete media units, such as identity cards, may provide more than one input method for receiving media units. For example, a group of media units may be placed in a hopper by an operator. In such devices, the weight of the group of media units itself may be employed to provide a pick roller configured to dispense media units from the hopper with sufficient traction. As the supply of media units is depleted, however, the pick roller may no longer have sufficient traction. As a result, such media processing devices may be provided with biasing assemblies configured to apply a consistent force on the remaining supply of media units in the hopper. However, such assemblies may then obstruct access to the hopper when an operator attempts to place additional media units therein, requiring manual retraction of the biasing assembly.
Another example input method accommodated by media processing devices is the use of an input slot to receive a single media unit. When a slot input is combined with the hopper input mentioned above, the media processing device utilizes additional components to feed media units into the required positions for processing from both input locations. Such additional components add complexity and cost, as well as additional potential points of failure. Another approach to accommodating both input methods may require an operator to remove the above-mentioned group of media units from the hopper before introducing a single media unit via the slot.
Additionally, media processing devices typically process a single media unit at a time. Therefore, media units are required to be consistently dispensed from the above-mentioned hoppers one at a time. This requirement is complicated by the need for some media processing devices to handle multiple thicknesses of media units, such as cards with thicknesses ranging from less than half a millimeter to more than one and a half millimeters. The components typically employed to ensure the dispensing of a single media unit from a hopper typically require manual adjustment to handle different card thicknesses. Such devices therefore require downtime before switching media unit types, and are at risk of mechanical malfunction if the above-mentioned adjustments are not made correctly.
Example methods and apparatus disclosed herein provide media processing devices with switchable drive mechanisms enabling the media processing devices to operate both slot-input components and a pick roller from a single power source (e.g., a motor). Further, example methods and apparatus disclosed herein provide media processing devices in which the switchable drive mechanisms also enable the media processing devices to operate the slot-input components, the pick roller, and an automatic biasing assembly release mechanism from a single power source (e.g., a motor). Further, example methods and apparatus disclosed herein provide media processing devices with input hoppers equipped to consistently singulate media units of varying thicknesses, without requiring manual adjustments.
Some example apparatus disclosed herein are directed to a media processing device including: a hopper for supporting a plurality of media units, the hopper including a biasing assembly for biasing the media units toward an outlet of the hopper; an input roller at a slot inlet configured to accept a single media unit into the hopper for placement adjacent to the outlet; a pick roller at the outlet for dispensing one of the media units from the hopper to a media processing path; a motor having an output shaft; a primary drivetrain segment connecting the output shaft with the pick roller; an auxiliary output selector connected to the primary drivetrain segment and switchable between a first output configuration and a second output configuration; a first auxiliary drivetrain segment connecting the auxiliary output selector with the input roller; a second auxiliary drivetrain segment connecting the auxiliary output selector with a release member configured to disengage the biasing assembly from the plurality of media units; and a selector input movable between (i) a first position for switching the auxiliary output selector to the first output configuration to couple the primary drivetrain segment with the first auxiliary drivetrain segment; and (ii) a second position for switching the auxiliary output selector to the second output configuration to couple the primary drivetrain segment with the second auxiliary drivetrain segment.
Turning to
A pick roller 208 is disposed at an outlet 212 of the input hopper 200, and is configured to dispense a single media unit 204 from the input hopper 200 to a media transport assembly configured to guide the media unit 204 along a media processing path 216. To inhibit the simultaneous release of more than one media unit 204 via the outlet 212, the media processing device 100 includes a gate wall 218 extending toward the outlet 212, as will be discussed below in greater detail.
The media processing device 100 also includes an input roller 220 at the slot 112, configured to drive a single media unit fed into the slot 112 underneath the stack of media units 204 already present (if any) in the input hopper 200. The single media unit fed into the slot 112 is then dispensed from the input hopper 200 for travel along the media processing path 216. In other words, the media processing device 100 is configured to process media units 204 retrieved from the stack in the input hopper 200, as well as single-feed media units received via the input slot 112. As will be discussed in greater detail below, the pick roller 208 and the input roller 220 are driven by a common motor.
The input hopper 200 also contains a biasing assembly 224 disposed above the stack of media units 204. The pick roller 208 dispenses the bottom media unit from the stack of media units 204 by frictionally engaging with the bottom media unit 204. If insufficient force is exerted by the bottom media unit on the pick roller 208, the frictional engagement between the pick roller 208 and the media unit may be too weak for the pick roller 208 to dispense the media unit. When the input hopper 200 is full, the weight of the stack of media units 204 alone may apply sufficient force for engagement between the bottom media unit and the pick roller 208. The biasing assembly 224 is configured to apply a progressively greater force to the top of the stack of media units 204 as the stack shrinks in size, thus maintaining a substantially constant force on the bottom media unit 204. The biasing assembly 224, in the present example, is implemented as a Sarrus linkage biased towards an open position in which the biasing assembly 224 applies a force on the media units 204 (the linkage is shown in a closed, or retracted, position in
The media transport assembly includes a plurality of rollers and guide surfaces. The media processing path 216, as seen in
During printing operations, an ink ribbon (not shown) travels from a supply roller 236 of the cassette 232 to the printhead 228, and then to a take-up roller 240 of the cassette 232. As the ink ribbon and the media unit 204 pass the printhead 228, the ink ribbon is in contact with the media unit 204. To generate the above-mentioned indicia, certain elements (e.g., printhead dots) of the printhead 228 are selectively energized (e.g., heated) according to machine-readable instructions (e.g., print line data or a bitmap). When energized, the elements of the printhead 228 apply energy (e.g., heat) to the ribbon to transfer ink to specific portions of the media unit 204.
In some examples, processing of the media unit 204 also includes encoding data in an integrated circuit, such as a radio frequency identification (RFID) tag, magnetic strip, or combination thereof, embedded in the media unit 204. Such processing may occur at the printhead 228 mentioned above, or at a distinct secondary processing head upstream or downstream of the printhead 228 along the media processing path 216.
Having traversed the printhead 228, the media unit 204 is transported along the media processing path 216 to the output hopper 116. In the present example, prior to arriving at the output hopper 116, however, the media unit 204 is transported to a media unit redirector 244 controllable to reverse, or flip, the media unit 204 by receiving the media unit 204, rotating by about 180 degrees, and expelling the media unit 204. Accordingly, the media transport assembly is configured to operate in two opposite directions along at least a portion of the media processing path 216 (illustrated in double lines). Specifically, the media processing path 216 proceeds in a return direction (as opposed to an outbound direction from the input hopper 200 to the printhead 228 and the redirector 244, described above) from the redirector 244 to the printhead 228. As a result of the media unit 204 having been flipped at the redirector 244, on the return pass of the printhead 228 an opposite side of the media unit 204 is exposed to the printhead 228 than on the outbound pass of the printhead 228. The media processing device 100, in other words, is capable of applying indicia to both sides of the media unit 204, before the media unit 204 is transported along the remainder of the media processing path 216 to the output hopper 116.
A media unit 204 travelling along the media processing path 216 may also be redirected from the media processing path 216 to an auxiliary processing path 248, also referred to as a media reject path. In the illustrated example, the redirector 244 is controllable, for example responsive to a detection of misaligned indicia applied at the printhead 228, a failed data writing operation to an embedded circuit in the media unit 204 or other defect, to rotate to a reject position at an angle other than 180 degrees from the resting position shown in
Turning to
As noted earlier, the biasing assembly 224 exerts a force (e.g., normal to the faces of the media units 204) on the stack of media units 204 within the input hopper 200. The biasing assembly 224 includes a pressure plate 304 movably coupled to the housing 104 (not shown in
Media units 204 can be placed into the input hopper 200 by rotating the door 108 about an axis 312 defined by a joint 316 (e.g., connected to the housing 104) from the closed position shown in
Media units 204 can also be introduced into the input hopper 200 via the slot 112 and the input roller 220, as mentioned earlier. A media unit 204 introduced via the slot 112 is propelled into the input hopper 200 between any media units 204 previously in the input hopper 200 and the floor 300. In other words, the slot 112 and input roller 220 serve to place a single media unit 204 adjacent to the outlet 212 for dispensing from the input hopper 200 toward the media processing path 216 by the pick roller 208.
The release member 320 and the input roller 220 are driven by a common power source. In addition, in the present example the pick roller 208 and the input roller 220 are driven by a common power source. Accordingly, in the illustrated example, a single motor 324 (e.g. an electric stepper motor) is configured to drive each of the input handling features mentioned above (the release member 320, the input roller 220 and the pick roller 208). The motor 324 is controllable, for example by a controller mounted on a substrate such as a circuit board 328, to drive an output shaft 330 of the motor 324 in one of two opposing directions. The output shaft 330 carries a rotational drive element, such as a gear or a belt-drive pulley, for connecting to components to be driven by the motor 324. In the illustrated example, a pinion gear 332 is mounted on the shaft 330.
The media processing device 100 includes a primary drivetrain segment connecting the output shaft (via the gear 332) to the pick roller 208. In the present example, the primary drivetrain segment includes a gear train implemented as a first gear 336 and a second gear 340 interconnecting the pinion 332 with a pick roller gear 344. The pick roller gear 344 rotates about the same axis as the pick roller 208. In the present example, as will be discussed in greater detail below, the pick roller gear 344 and the pick roller 208 are mounted on a common shaft 348 rotatably supported by the housing 104. The pick roller 208 is fixed to the shaft 348, whereas the pick roller gear 344 is mounted on the shaft 348 on a one-way clutch (not shown in
The media processing device 100 also includes an auxiliary output drive selector 352 (also referred to herein as the selector 352) connected to the primary drivetrain segment and switchable between a first output configuration and a second output configuration. In particular, the selector 352 is connected to the pick roller gear 344 via engagement of gear teeth on the selector 352 and the pick roller gear 344.
The selector 352 is configured, in the first output configuration mentioned above, to connect (i.e. to engage in order to transmit motive force) the primary drivetrain segment (e.g., the gear train ending at the pick roller gear 344) with a first auxiliary drivetrain segment between the selector 352 and the input roller 220. The first auxiliary drivetrain segment is defined, in the present example, by a gear 356 and an input roller gear 360. The gear 360 is fixed to a shaft on which the input roller 220 is also fixed. In other examples, the gear 360 engages the selector 352 directly (i.e. the gear 356 is omitted). In further examples, additional gears are positioned in a gear train between the selector 352 and the input roller gear 360 to implement the first auxiliary drivetrain segment.
The selector 352 is also configured, in the second output configuration mentioned above, to connect the primary drivetrain segment (e.g., the gear train ending at the pick roller 344) with a second auxiliary drivetrain segment between the selector 352 and the release member 320. The second auxiliary drivetrain segment is defined, in the present example, by a gear 364 connecting the selector 352 and the release member 320. In other examples, a greater number of gears or other rotational drive elements (e.g. belt-driven pulleys) are employed to implement the second auxiliary drivetrain segment. Further, in the present example the release member 320 is a sector gear having teeth directly engaged with the gear 364. In other examples, the release member 320 is instead mounted on a shaft bearing an additional gear engaged with the gear 364.
As will be discussed below, the selector 352 is switchable between the first and second output configurations such that the output configurations are mutually exclusive. That is, the selector 352 is configured, in either configuration, to connect the primary drivetrain segment to only one of the two auxiliary drivetrain segments mentioned above. As will also be discussed below, the selector 352 is configured to transmit power from the motor 324 along the auxiliary drivetrain segments described above responsive to rotation of the pinion 332 in only one direction. When the motor 324 drives the pinion 332 in the opposite direction, the selector 352 is configured not to transmit power to the release member 320 or the input roller 220, regardless of which output configuration the selector 352 is set to.
The selector 352, therefore, is configured to be driven by the primary drivetrain segment described above, and to switch between driving the first and second auxiliary drivetrain segments described above. The selector 352 is switched via the movement of a movable selector input, having a first position for switching the auxiliary output selector to the first output configuration, and a second position for switching the auxiliary output selector to the second output configuration. As will be described in greater detail below, the selector input is implemented in this example as a cam 368 formed on the joint 316 of the door 108. Rotation of the door 108 toward the open position rotates the cam 368 and switches the selector 352 to the second output configuration, while rotation of the door 108 to the closed position (shown in
Turning to
The selector 352 also includes a first output rotational drive element, which in the present example is a first output rotational drive element (e.g., a gear) 408, connected to the first auxiliary drivetrain segment. In particular, the first output gear 408 is connected to the gear 356 shown in
The selector 352 further includes a second output rotational drive element, which in the present example is a second output rotational drive element (e.g., a gear) 420, connected to the second auxiliary drivetrain segment. In particular, the second output gear 420 is connected to the gear 364 shown in
The output gears 408 and 420 are mounted to rotate freely on the selector drive shaft 404. The selector disc 416 is mounted on the selector drive shaft 404 via a one-way clutch 424, and is movable in an axial direction (that is, in a direction parallel to the axis of the shaft 404) over the clutch 424. In particular, the selector disc is movable between a first position and a second position. In the first position, a first set of teeth 428 or other engagement surfaces on a side of the selector disc 416 facing the first output gear 408 engage with the teeth 412. In the second position, a second set of teeth 432 or other engagement surfaces on an opposite side of the selector disc facing the second output gear 420 engage with the teeth 422. In the present example, the teeth 412 and 428 are ramped in opposite directions to inhibit misalignment of the teeth 412 and 428. The teeth 422 and 432 are also ramped in opposite directions to inhibit misalignment of the teeth 422 and 432. The above-mentioned ramps permit the teeth 412 and 428 (as well as the teeth 422 and 432) to slide against each other in one direction and engage in the other direction.
When the selector disc is in the first position, the teeth 432 are spaced apart from the teeth 422, and the selector disc 416 therefore drives the first output gear 408, but not the second output gear 420. In the second position, on the other hand, the teeth 412 and 428 are spaced apart, and the selector disc 416 therefore drives the second output gear 420, but not the first output gear 408. As noted above, the selector disc 416 is mounted on the shaft 404 via the clutch 424. The clutch 424 is configured to engage the selector disc 416 with the shaft 404 when the shaft 404 rotates in a first direction (counterclockwise in the orientation shown in
The selector disc 416 is moved between the above-mentioned first and second positions by a selector input in the form of the cam 368, as noted above. The cam 368 is disposed on the joint 316 at a non-right angle relative to the axis 312 about which the door 108 rotates. The cam is configured to engage the selector 352 to place the selector disc 416 in the second position mentioned above when the door 108 is open, and to place the selector disc 416 in the first position mentioned above when the door 108 is closed. The interaction between the cam 368 and the selector disc, in the present example, is mediated by a cam follower, such as a collar 436 slideable in an axial direction along a shaft 440 mounted to the housing 104. The collar 436 includes a pair of posts disposed on either side of the cam 368. Due to the angle of the cam 368, rotation of the joint 316 brings the cam into engagement with one or another of the posts 444 and forces the collar 436 to slide along the shaft 440. The selector disc 416 is rotatably received within the collar 436, and therefore when the collar slides along the shaft 440, the selector disc 416 slides over the clutch 424 between the first and second positions mentioned above. In other examples, the collar 436 is replaced with an alternative cam follower, such as opposing rims extending from the perimeter of the disc 416 to engage the cam 368.
Turning to
Having described the components of the input handling system of the media processing device 100, the operation and control of those components will now be discussed in greater detail, beginning with the receipt of a media unit 204 via the input slot 112. As seen in
The controller, responsive to detection of input motion via the gap sensor 504, is configured to control the motor 324 to drive the output shaft 330 and pinion 332 in a first direction. In the example media processing device 100 as illustrated in
The rotation of the input roller gear 360 in a clockwise direction serves to drive the inserted media unit 204 into the hopper 200. Rotation of the pick roller gear 344 in a counterclockwise direction does not result in movement of the pick roller 208 itself, as a result of the clutch 500. The controller is configured to drive the motor 324 in the above-mentioned first direction for a predetermined operational period. In the present example, the controller configures the motor to drive the output shaft 330 in the first direction for a predetermined number of steps. In other examples, the operational period is instead defined as a time period, a number of encoder teeth 508 detected by the sensor 504, or the like. The controller is then configured to control the motor 324 to drive the output shaft 330 in a second direction opposite the first direction.
Rotation of the output shaft 330 and the pinion 332 in the second direction results in rotation of the pick roller gear 344 in a clockwise direction, in which the clutch 500 engages the shaft 348. The pick roller 208 is therefore driven, and the media unit 204 that was inserted at the slot 112 and driven into the hopper 200 by the input roller 220 is dispensed from the hopper 200 toward the media processing path 216. The input roller 220, meanwhile, ceases to rotate. In particular, the clutch 424 of the selector 352 permits the selector disc to rotate freely about the shaft 404 when the input gear 400 is driven counterclockwise (again, in the orientation shown in
Turning now to
Upon detection that the door 108 is open, the controller is configured to initiate operation of the motor 324 to drive the output shaft in the first direction mentioned above. As noted earlier, when the pinion 332 is driven in the first direction, the pick roller 208 remains stationary as a result of the clutch 500, but the selector disc 416 is driven by the shaft 404 via the clutch 424. Accordingly, when the door 108 is open and the motor 324 is controlled to drive the output shaft 330 in the first direction, the second output gear 420 of the selector 352 is driven (in the orientation shown in
The media processing device 100 also includes a release member limit sensor 604 (e.g. mounted to the circuit board 328) configured to detect that the release member 320 has reached a position fully disengaging the biasing assembly 224. In the present example, the sensor 304 is a reflectivity sensor configured to detect a change in reflectivity resulting from the traversal of a gap 608 in the release member 320 in front of the sensor 604. In other examples, other suitable limit sensors can be implemented instead of, or in addition to, the reflectivity sensor 604. Upon detection of the gap 608, the controller is configured to cease operation of the motor 324.
After the door 108 returns toward the closed position, the cam 368 shifts the selector disc 368 (via the collar 436) back to the first output configuration, and the release member 320 is therefore permitted to rotate freely. As a result, the biasing assembly 224 extends toward the floor 300 of the hopper 200. The biasing assembly 224 can also be raised manually by an operator of the media processing device 100, for example when the media processing device 100 is powered off.
Turning now to
The flexible gate includes a lower portion 712 extending beyond the end of the gate wall 218 into the outlet 212. At least the lower portion 712 of the flexible gate, and in the present example the entirety of the flexible gate 700, is made from a resilient, flexible material. For example, the flexible gate 700 is made of a plastic, including thermoplastics such as polyoxymethylene. The lower portion 712 is configured to deflect toward the media processing path 216 (that is, away from the interior of the hopper 200) responsive to the outer media unit within the hopper 200 being driven into the lower portion 712 of the flexible gate 700 by the pick roller 208. The deflection of the lower portion 712 permits the outer media unit 204 to be dispensed from the hopper 200, while inhibiting or preventing additional media units 204 from being dispensed simultaneously with the outer media unit 204. Further, the pick roller 208 and the bias assembly 224 cooperate to drive media units 204 from the hopper 200 into the outlet 212 such that each media unit 204 impacts the lower portion 712 with substantially equal force. As will be discussed below, the lower portion 712 includes an angled impact surface that is configured to deflect toward the media processing path 216 by a variable distance, based on the thickness of the media unit 204. The lower portion 712 also includes a passive roller 716 oriented perpendicularly to the media processing path 216 in the present example, for guiding the media unit 204 dispensed from the hopper 200 into the media processing path 216.
Turning to
An overly shallow angle 804 (measured relative to vertical, as illustrated in
Variations to the above are contemplated. In some examples, one or the other of the input roller 220 and the release member 320 can be either omitted or driven by a motor distinct from the motor 324. In such examples, the other of the input roller 220 and the release member 320 can be connected to the primary drivetrain segment via a one-way clutch rather than via the selector 352.
In the foregoing specification, specific embodiments have been described. However, one of ordinary skill in the art appreciates that various modifications and changes can be made without departing from the scope of the invention as set forth in the claims below. Accordingly, the specification and figures are to be regarded in an illustrative rather than a restrictive sense, and all such modifications are intended to be included within the scope of present teachings.
The benefits, advantages, solutions to problems, and any element(s) that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential features or elements of any or all the claims. The invention is defined solely by the appended claims including any amendments made during the pendency of this application and all equivalents of those claims as issued.
Moreover, in this document, relational terms such as first and second, top and bottom, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. The terms “comprises,” “comprising,” “has”, “having,” “includes”, “including,” “contains”, “containing” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises, has, includes, contains a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. An element proceeded by “comprises . . . a”, “has . . . a”, “includes . . . a”, “contains . . . a” does not, without more constraints, preclude the existence of additional identical elements in the process, method, article, or apparatus that comprises, has, includes, contains the element. The terms “a” and “an” are defined as one or more unless explicitly stated otherwise herein. The terms “substantially”, “essentially”, “approximately”, “about” or any other version thereof, are defined as being close to as understood by one of ordinary skill in the art, and in one non-limiting embodiment the term is defined to be within 10%, in another embodiment within 5%, in another embodiment within 1% and in another embodiment within 0.5%. The term “coupled” as used herein is defined as connected, although not necessarily directly and not necessarily mechanically. A device or structure that is “configured” in a certain way is configured in at least that way, but may also be configured in ways that are not listed.
It will be appreciated that some embodiments may be comprised of one or more generic or specialized processors (or “processing devices”) such as microprocessors, digital signal processors, customized processors and field programmable gate arrays (FPGAs) and unique stored program instructions (including both software and firmware) that control the one or more processors to implement, in conjunction with certain non-processor circuits, some, most, or all of the functions of the method and/or apparatus described herein. Alternatively, some or all functions could be implemented by a state machine that has no stored program instructions, or in one or more application specific integrated circuits (ASICs), in which each function or some combinations of certain of the functions are implemented as custom logic. Of course, a combination of the two approaches could be used.
Moreover, an embodiment can be implemented as a computer-readable storage medium having computer readable code stored thereon for programming a computer (e.g., comprising a processor) to perform a method as described and claimed herein. Examples of such computer-readable storage mediums include, but are not limited to, a hard disk, a CD-ROM, an optical storage device, a magnetic storage device, a ROM (Read Only Memory), a PROM (Programmable Read Only Memory), an EPROM (Erasable Programmable Read Only Memory), an EEPROM (Electrically Erasable Programmable Read Only Memory) and a Flash memory. Further, it is expected that one of ordinary skill, notwithstanding possibly significant effort and many design choices motivated by, for example, available time, current technology, and economic considerations, when guided by the concepts and principles disclosed herein will be readily capable of generating such software instructions and programs and ICs with minimal experimentation.
The Abstract of the Disclosure is provided to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. In addition, in the foregoing Detailed Description, it can be seen that various features are grouped together in various embodiments for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed embodiments require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter lies in less than all features of a single disclosed embodiment. Thus, the following claims are hereby incorporated into the Detailed Description, with each claim standing on its own as a separately claimed subject matter.
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