Printing devices are arranged to print ink on to different media, which can include corrugated media. An example printing device comprises one or more print heads, each print head comprising one or more nozzles. These nozzles are arranged to deposit ink droplets onto media. The printed media may then coated with printing fluid such as varnish or gloss by directly applying a surface, such as a roller, coated in the printing fluid to the printed media.
Various features of the present disclosure will be apparent from the detailed description which follows, taken in conjunction with the accompanying drawings, which together illustrate features of the present disclosure, and wherein:
In the following description, for purposes of explanation, numerous specific details of certain examples are set forth. Reference in the specification to “an example” or similar language means that a particular feature, structure, or characteristic described in connection with the example is included in at least that one example, but not necessarily in other examples.
As described herein, an example printing system comprises an array of nozzles and a print controller. The array of nozzles are arranged to deposit printing fluid, such as ink, gloss or varnish, on to a sheet of corrugated media, such as cardboard. In one example, the array of nozzles may be used instead of applying gloss or varnish by contacting printed media with a surface coated in the gloss or varnish. In another example, the array of nozzles may deposit ink onto corrugated media to form an image.
An example corrugated media comprises corrugations located between two outer layers. If the corrugated media is substantially flat, the media will be covered evenly by the printing fluid. However, in some circumstances corrugated media may be deformed, for example the media may be warped, bent, creased or dented. This may be a result of the manufacturing process itself, as a result of improper storage or handling of the media, or as a result of moisture in the ink printed onto the media, for example. If the printing fluid were to be applied normally to deformed media, the printing fluid may be applied non-uniformly, which can cause undesirable visible effects, such as lines and a change in gloss or colour hue. Accordingly, an example printing system described herein can adapt how the printing fluid is applied depending upon the level of deformation. An example method performed by the printing system comprises determining the deformation of the corrugated media. For example, the printing system may be arranged to determine, measure, record, or quantify the deformation of the corrugated media before depositing the printing fluid on to the media. Once determined, control parameters for the plurality of nozzles may be adjusted, based on the determined deformation, before depositing the printing fluid from the plurality of nozzles onto the sheet of corrugated media. In this manner, the printing fluid may be applied in a manner suitable for the deformation, thus reducing or even eliminating the presence of these unwanted visual effects. The print controller of the printing system may therefore be configured to receive sensor data of the sheet of corrugated media. The print controller determines the deformation of the sheet of corrugated media based on the sensor data and adjusts control parameters for the array of nozzles based on the deformation. The print controller may control the array of nozzles to deposit printing fluid onto the sheet of corrugated media based on the adjusted control parameters. Accordingly, the example printing system can apply printing fluid on corrugated media without affecting the structural integrity of the corrugated media and without introducing unwanted visible effects.
The print controller 108 may also be connected, directly or indirectly to the array of nozzles 102 via a communication path 114 to allow the transmission of data between the print controller 108 and the array of nozzles 102. The communication path 114 allows the print controller 108 to control the array of nozzles 102 as a whole, and/or control each nozzle 104 individually. The print controller 108 may send control signals/instructions along the communication path 114, which cause the array of nozzles 102 and/or each nozzle 104 to respond according to the instruction. For example, the instructions may cause one or more nozzles 104 to adjust their angle of tilt, their vertical distance from the sheet of corrugated media 106, their spray angle, their spray flow intensity, and/or their motion. These instructions sent by the print controller 108 may be different depending upon the deformation of the corrugated media 106.
In some examples, the corrugated media 106 may be stationary when the printing fluid is applied by the nozzles 104. However, in the examples of
As mentioned above, corrugated media may not always be flat because it is particularly prone to being deformed.
In the example of
To compensate for the deformation of the corrugated media 406c, the deformation can first be determined, measured, calculated, or estimated by the printing system 100. The deformation can be determined through use of the sensor device 110, to measure or record sensor data. In one example, the deformation may be determined by taking an image of the corrugated media 406c using a camera. For example, a camera may comprise, or the camera may be, the sensor device 110 depicted in
In some examples, there may be more than one sensor device 110, for example there may be two or more cameras used to image the corrugated media 406c. In one specific example, a first camera is used to take an image of a side profile of the corrugated media 406c, and a second camera is used to take an image of the corrugated media 406c from above. Both images can be used by the print controller 108 to determine the deformation.
In some examples, the deformation is determined automatically, with little or no human input.
In one example, the deformation may be fully or partially determined by impinging electromagnetic radiation onto the surface of the corrugated media 406c and detecting the reflected electromagnetic radiation using a sensor device 110. Therefore in some examples the printing system 100 may also comprise an electromagnetic source device. The reflected intensity, time delay, and/or angle of incidence into the sensor device 110 may be used to determine the deformation of the corrugated media 406c. Data captured by the sensor device 110 can be used to determine the deformation, which again may be analysed using known image processing software. In some examples, the electromagnetic source device may be used in conjunction with one or more cameras. The electromagnetic radiation may be visible light, infra-red, or ultraviolet for example.
In a further example, ultrasound may be used to determine the deformation, whereby sound waves are reflected from the surface of the corrugated media 406c and detected using an appropriate sensor device 110.
The sensor device 110 may be used to sense the deformation before or while the corrugated media 106 is located on the conveyor belt 116. The corrugated media 106 may be stationary or in motion when the sensor device 110 collects sensor data.
Regardless of how the sensor device 110 is used to capture sensor data of the sheet of corrugated media 406c, the print controller 108 uses or analyses the sensor data to determine or estimate the deformation.
In an example, determining the deformation of the sheet of corrugated media 406c comprises determining height displacements of a plurality of locations on the sheet 406c with respect to a reference height. In one example, a side profile image captured by a camera may be analysed using a software program to estimate the height of a number of points along the sheet 406c. Any number of known algorithms may be invoked to detect the surface of the corrugated media 406c within the image. A number of predefined or arbitrary locations can be selected along this surface and their height displacement can be calculated. The height displacement may be calculated by counting the number of pixels each location is displaced from a reference location within the image, for example. In another example, sensor data from reflected sound waves or electromagnetic radiation may be used to calculate the height displacements of a plurality of locations.
Once the height displacements of a plurality of locations have been determined, a height displacement of at least one additional location on the sheet may be estimated based on the determined height displacements of the plurality of locations. In one example, this is performed by extrapolation using the determined height displacements of the plurality of locations on the sheet. In another example, this is performed by interpolation using the determined height displacements. Known methods of extrapolation and interpolation may be used. Accordingly, a more complete representation of the deformation can be determined based on a few initial measurements.
In some examples, an image captured by the camera can be used to generate a model of the sheet based on the captured image. As described above, a side profile image captured by a camera may be analysed using a software program detect the surface of the corrugated media 406c within the image. Once detected, a model can be generated using the image data. In one specific example, two or more cameras may each capture an image of the corrugated media from different angles. These images can be used to build a one, two, or three-dimensional model of the sheet. The generated model provides an accurate representation of the deformation which can be used by the print controller 108.
In some examples, the model may be described or approximated as a mathematical function expressed in one or more spatial dimensions. For example, flat corrugated media may be approximated as a one-dimensional function, and concave or convex corrugated media may be approximated as a two-dimensional function, or a three-dimensional function. Wave-like corrugated media may also be approximated as a two-dimensional function, or as a three-dimensional function. A two-dimensional function therefore approximates, or assumes the deformation is uniform along the third dimension, whereas a three-dimensional function may more accurately express the deformation of the whole surface of the corrugated media. Expressing the model as a mathematical function can allow control parameters to be more easily determined. Furthermore, gradients can be more easily calculated for different locations on the surface through the use of well-defined mathematical functions.
In one example, a mathematical function may be determined from an image taken of the corrugated media 406c. For example, a side profile image captured by a camera may be analysed using a software program to detect the surface of the corrugated media 406c within the image. Coordinate locations along this surface may be input into a least squares fitting algorithm, for example, to determine a mathematical function that most closely describes the surface.
Once the deformation has been determined, control parameters for the plurality of nozzles can be adjusted based on the deformation. Based on these adjusted control parameters, the print controller 108 may control a plurality of nozzles such that deposited printing fluid is applied according to the adjusted control parameters to ensure an even coating of the printing fluid. In an example, a set of rules may be defined and followed that adjust the control parameters to compensate for particular types and levels of deformation. For example, the gradient of the surface may be calculated or determined at one or more locations on the corrugated media, and based on the gradient the set of rules may specify that the nozzle 104, and/or adjacent nozzles 104 should be configured with specific control parameters.
One or more control parameters may be adjusted. In one example, an angle of tilt of a nozzle can be adjusted. For example, a nozzle may be rotated about one or more axes by an actuator, such as a motor. In
In another example, a vertical distance of a nozzle can be adjusted, where the vertical distance is defined as a distance perpendicular to the direction of motion of the media 406c, in the direction indicated by arrow D. For example, a nozzle's vertical distance from the sheet 406c may be adjusted by an actuator, such as a linear motor. In
In another example, a spray angle of a nozzle can be adjusted. For example, a nozzle's spray angle may be adjusted by increasing or decreasing an aperture in the nozzle through which the printing fluid passes. In
In another example, a spray flow intensity of a nozzle can be adjusted. For example, a nozzle's spray flow intensity may be adjusted by increasing or decreasing the pressure applied to the printing fluid before being ejected by the nozzle. In
In another example, the motion of a nozzle can be adjusted. For example, a nozzle's motion may be adjusted independently of the other nozzles 104 in the array of nozzles 102. The motion may be adjusted by an actuator, such as a linear actuator. In
Therefore, as mentioned, adjusting any or all of these control parameters in dependence on the deformation of the corrugated media, ensures a more uniform layer of print fluid is applied.
As indicated above, each nozzle 104 may be associated with one or more actuators to control motion in one or more directions or to control an angle of tilt. Each nozzle 104 may also be associated with an aperture and a print fluid pressure device. Each of these means for adjustment associated with the nozzles 104 are used to adjust different parameters according to control parameters determined by the print controller 108. Although specific adjustment means have been described, in some examples other known adjustment means may be used to adjust the different parameters.
In some examples, the control parameters may be adjusted for one nozzle 104 or a single nozzle 104, however in other examples the control parameters may be adjusted for more than one nozzle 104.
Control parameters may be expressed as a sequence of control parameters in time. For example, at a first time, t1, a first nozzle may be configured according to first control parameter, and at a second, later time, t2, the first nozzle may be configured according to a second control parameter. Adjustments to the nozzles control parameters may be made on the order of microseconds, milliseconds, or seconds, for example.
It will be appreciated that a control parameter for a particular nozzle may include control parameters for any or all of: an angle of tilt of the nozzle, a vertical distance of the nozzle from the sheet, a spray angle of the nozzle, a spray flow intensity of the nozzle, and/or a motion of the nozzle. Other control parameters may also be adjusted.
Signals sent along the communication paths 112, 114 may be sent using any appropriate communication protocol. The communication paths 112, 114 may be wired or wireless communication paths.
In some example methods, determining the deformation of a sheet of corrugated media may comprise determining height displacements of a plurality of locations on the sheet with respect to a reference height, and estimating a height displacement of at least one additional location on the sheet based on the determined height displacements.
In some example methods, estimating the height displacement of an additional location on the sheet may be based on at least one of: an extrapolation of the determined height displacements of the plurality of locations on the sheet and an interpolation of the determined height displacements of the plurality of locations on the sheet.
In some example methods, determining the deformation of a sheet of corrugated media may comprise capturing an image of the sheet by a camera, and generating a model of the sheet based on the captured image. In some examples there may be more than one camera, each camera capturing one or more images, such that the model generated is based on some or all of the captured images.
In some example methods, determining the deformation of a sheet of corrugated media may comprise capturing sensor data using a sensor device, and generating a model of the sheet based on the sensor data.
In some example methods, generating a model of the sheet based on the captured image may comprise approximating the sheet as a mathematical function in at least one dimension. In one example, a concave or convex deformation may be approximated as a quadratic function expressed in two spatial dimensions.
In some example methods, adjusting the control parameters for the plurality of nozzles comprises adjusting at least one of: an angle of tilt of a nozzle, a vertical distance of a nozzle from the sheet, a spray angle of a nozzle, a spray flow intensity of a nozzle, and a motion of a nozzle.
In some example methods, a direction of motion of the sheet of corrugated media is perpendicular to a direction of the motion of the nozzle.
In some example methods, the printing fluid is one of an ink, a gloss, or a varnish.
Certain system components and methods described herein may be implemented by way of non-transitory computer program code that is storable on a non-transitory storage medium. In some examples, the print controller 108 may comprise a non-transitory computer readable storage medium comprising a set of computer-readable instructions stored thereon. The print controller 108 may further comprise one or more processors. In some examples, control may be split or distributed between two or more controllers 108 which implement all or parts of the methods described herein.
In an example, instructions 602 cause the processor 604 in a printing system to, at block 606 receive sensor data from a sensor device connected to, or integral with, the printing system. At block 608, the instructions 602 cause the processor 604 to use the sensor data to determine height displacements of a plurality of locations on the sheet with respect to a reference height. At block 610, the instructions 400 cause the processor 604 to estimate a height displacement of at least one additional location on the sheet based on the determined height displacements. At block 612, the instructions 602 cause the processor 604 to generate control data for a plurality of nozzles based on the determined height displacements and estimated height displacement. At block 614, the instructions 602 cause the processor 604 to adjust control parameters for the plurality of nozzles based on the control data. At block 612, the instructions 602 cause the processor 604 to deposit printing fluid from the plurality of nozzles onto the sheet of corrugated media according to the adjusted control parameters.
In some examples, the instructions 602 may further cause the processor 604 to adjust the control parameters for the plurality of nozzles by adjusting at least one of: an angle of tilt of a nozzle, a vertical distance of a nozzle from the sheet, a spray angle of a nozzle, a spray flow intensity of a nozzle, and a motion of a nozzle.
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17184098 | Jul 2017 | EP | regional |
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Number | Date | Country | |
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20190030887 A1 | Jan 2019 | US |