Printing systems may use a cartridge that provides for a printing material, for example a liquid. The cartridge may provide printing material such as ink and/or may host further or alternative systems.
Examples will now be described, by way of a non-limiting example only, with reference to the accompanying drawings, in which:
Equal or equivalent elements or elements with equal or equivalent functionality are denoted in the following description by equal or equivalent reference numerals even if occurring in different figures.
In the following description, a plurality of details is set forth to provide a more thorough explanation of examples of the present disclosure. However, examples of the present disclosure may be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form rather than in detail in order to avoid obscuring examples of the present disclosure. In addition, features of the different examples described hereinafter may be combined with each other, unless specifically noted otherwise.
Examples described herein relate to collecting a waste printing material, i.e., material that is provided in excess when compared to printing material that is actually printed by the printing system. Although the examples described herein relate to a cartridge and a printing system that may use ink to be printed, the concept of collecting waste printing material and to indicate a filling level of a container or volume for collecting the waste printing material, i.e., a receptacle, may be used or transferred, without limitation, to receptacles for collecting any type of wet liquid printing material.
An example for collecting waste printing material is executed in a spittoon subsystem of a printing system that accumulates waste. Examples herein provide for a concept to provide for information indicating the level of the waste printing material so as to avoid leakage of the waste printing material out of the receptacle. Such waste printing material may have its origin from missing drops caused, for example, by the clogging of nozzles in a printhead (PH) of a printing system, or a bad final position of the drop of ink onto a print target due to a misdirected firing. A print target may be a 2D media, e.g., a flat sheet, but may also be a substrate, bed or base onto which a 3D structure is printed using build material.
The receptacle 14 may be integrally formed with the cartridge 101 or a main body or a substrate thereof. The receptacle 14 provide for a volume to receive, collect a store the waste printing material 12. The receptacle 14, wall structures thereof respectively may comprise a solid material such as a plastic material, a metal material or the like. The wall structures may limit the receptacle 14 at sides, a bottom and/or a top of the volume. An opening in a wall structure and/or an at least partially missing wall structure, e.g., an at least partially missing top wall such as a lid or cap, may provide for an inlet of the waste printing material 12 into the receptacle 14, wherein the waste printing material may be received under pressure or pressure-less.
The cartridge 101 comprises a floater 16 that may float or drift on or in the waste printing material 12. The floater 16 may comprise material and/or a relative overall density that is below a density of the waste printing material 12 so as to allow a floating or drifting of the floater 16 on or in the waste printing material. For example, the floater 16 may comprise a plastic material. Alternatively or in addition, the floater may be formed as a hollow body.
An example printing system is an inkjet printer, wherein the waste printing material 12 may be a liquid. According to examples, the printing system is a 2D or 3D printing system and may alternatively or in addition to the liquid print a dry or powdered printing material such that the receptacle may also contain such a dry or powdered or liquidized powdered material. Alternatively or in addition, the condition of the waste printing material may vary over time. For example, the waste printing material may be put into the receptacle 14 as liquid ink. Over time, a portion of the waste printing material 12 such as water and/or other solvents may evaporate such that the waste printing material 12 becomes more solid like. The waste printing material 12 may thus get into a state being referred to as dried out liquid material.
The floater 16 may change its position based on a varying filling level of the waste printing material 12 in the receptacle 14. For example, with an increase in the filling level a surface of the waste printing material 12 and thereby of the floater 16 may travel towards a positive filling direction 18.
The cartridge 101 may comprise a flag 22 being mechanically coupled to the floater 16. The flag 22 may be coupled to the floater 16 directly or indirectly, e.g., via a mechanical element 24, such as a rigid body or a set thereof so as to induce a movement of the flag 22 responsive to a movement of the floater 16. A position of the flag 22 may thus depend on the position of the floater 16. The position of the flag 22 may indicate the filling level of the waste printing material 12 outside the receptacle 14. A direction 26 of the movement of the flag 22 may be in parallel with the filling direction 18 but may also be directed towards a different direction.
According to an example, the flag 22 may protrude or project or stick out of the receptacle 14 on a top side of the receptacle 14. According to examples, at varying filling levels of the waste printing material 12, the flag 22 may protrude with a constant, or alternatively, varying size or dimension at a side of the receptacle 14, the cartridge respectively. The flag may thus move based on the filling level, the movement and/or resulting position indicating a variation in the filling level.
The flag 22 may have any shape or geometry and may serve as an indicator to be detected by the naked eye and/or by a sensor element. The position of the flag 22 indicating the filling level of the waste printing material 12 in the receptacle 14 may refer to a position of the flag 22, but may also refer to a visible size of the flag 22.
The flag 22 may be of any material, for example, a metallic material such as copper, iron, steel or aluminum and/or may comprise a plastic material and/or a semiconductor material and/or a fiber material such as paper, wood or fiber reinforced plastic.
Alternatively or in addition, the flag 22 may protrude or stick out of the receptacle 14 with a varying size based on the filling level. For example, with an increase in the filling level, i.e., a movement of the floater 16 along the direction 18, an increasing size of the flag 22 may protrude out of the receptacle 14 and/or of the cartridge 103 such that the size being visible outside the receptacle 14, the cartridge 103 may be evaluated and/or indicate the filling level.
As described in connection with
Although the cartridges 101, 102, 103 and 104 are described as to show for an increase in height and/or size of the flag 22 outside of the receptacle 14 and/or the cartridge with an increase of the filling level, according to an example, a mechanism may be arranged so as to invert the movement of the flag 22. That is, a visible or evaluable size of the flag 22 may decrease with an increase of the filling level. For example, a lever mechanism may be arranged.
As shown, a position outside of the receptacle 14, the cartridge respectively, e.g., a presence or absence at an evaluated region and/or a visible or evaluable size of the flag 22 may indicate a magnitude or amount of the filling level.
Rotating of the lever element 32 at the bearing region 34 along the rotational direction 36 may allow the flag 22 to increasingly stick out of the cartridge 20 with an increase or decrease of the filling level so as to indicate the filling level present inside the receptacle 14 to an outside thereof thereby enabling an evaluation or monitoring of the filling level outside the receptacle and thereby allowing for a timely change or evacuation of the receptacle to prevent an overflow of the receptacle 14.
When compared to
Such information may alternatively or in addition encoded by optical or mechanical structures 39a to 39c acting on a motor, e.g., lines, circles, triangles or the like. A number of structures 39a to 39c that has passed the motor or is visible may indicate a longer or shorter length and thus a fuller container.
A first portion 44a of the mechanical actuator 44 may provide for the mechanical contact to the respective portion of the indicator arrangement comprising the floater 16, the flag 22 and mechanical elements arranged therebetween or attached hereto. A second portion 44b may at least partially stick out of the cartridge 30 in a reference position that may be obtained, for example, by use of a spring element 46. The second portion 44b, the portion thereof sticking out of the cartridge respectively, may intermittently mechanically engage with a static portion of a printing system into which the cartridge 30 is mounted. The static portion may be a wall of the printing system, or any other portion thereof that allows for an impact of the second portion 44b. By mechanically engaging with the static portion, the mechanical actuator may move relative to the cartridge 30, thereby mechanically engaging with the indicator arrangement at the first portion 44a. Additionally, the spring element 46 may be charged or stressed or enlarged so as to store energy. As soon as the cartridge 30 leaves this position, e.g., a homing position of the cartridge 30, the charged spring element 46 may lead the mechanical actuator 44 to disengage with the indicator arrangement and to reposition the second portion 44b outside of the cartridge 30. After having disengaged the indicator arrangement, the mechanical actuator may keep in the position of the floater unchanged with respect to the floating position.
In other words, there is the possibility of the floater sticking to the waste, preventing it from floating. To avoid this effect, examples provide for a mechanism such that every time that the maintenance cartridge goes to the rear homing position, the floater is lifted off of the waste.
The printhead cleaning system 40 may comprise a sensor element 54 to detect the flag 22 outside the receptacle, the cartridge 20 respectively. The sensor element 54 may be arranged stationary, i.e., at the printing arrangement 52 and/or may be arranged at the cartridge 20, thereby moving with the cartridge 20. Arranging the sensor element 54 stationary with respect to the cartridge 20 allows the sensor element 54 to be synergistically used for detecting or monitoring the flag 22 and/or for determining a position of the cartridge 20 with respect to the printing arrangement 52, for example, by monitoring a position of flags 561 and/or 562 mounted to an outer surface of the cartridge 20. The flags 561 and/or 562 may thus indicate a position of the mobile servicing system in the printhead cleaning system 40 and may thus allow to prevent detecting the cartridge 20 to be at a homing position based on a motor current of a motor driving the cartridge 20. This may allow for precise and simple arrangements and determinations of the position of the cartridge 20.
The sensor element 54 may be of an electrical, a magnetic and/or an optical type. For example, the sensor element 54 may sense, measure or detect a magnetic field of a magnet attached to the cartridge 20. Alternatively or in addition, a capacitive and/or inductive sensor may be used. According to an example, the sensor element 54 may be implemented as an optical sensor that may monitor or detect a position of the flags 561 and/or 562.
The sensor element 54 may output a sensor signal indicating a degree of filling of the receptacle 14. For example, the sensor element 54 may output a sensor signal indicating that a degree of filling of the receptacle of the cartridge 20 is at least a filling threshold level. A single filling threshold level or a plurality thereof may be used, for example, allowing for different regions of filling such as empty, partially filled, almost full and/or full. The printhead cleaning system 40 may provide a signal indicating that the degree of filling is at least the filling threshold level. A signal may be provided, for example, to a user. This may be implemented, for example, as an optical, acoustic and/or electronic signal.
Although the printhead cleaning system 40 is described as comprising the cartridge 20, alternatively or in addition, the cartridges 101, 102, 103, 104 and/or 30 may be arranged.
Examples describe a floating flag to measure the waste level and/or to a lifter, i.e., mechanical actuator 44, to avoid the floater sticking to the waste. Examples allow for a continuous measure of the level with an optical sensor to detect the flag 22. Some of the subsystems of the printhead cleaning system 40 are fixed to the printer while others are mobile and can be replaced at the end of the live of a system. Examples described herein are especially useful in mobile components such as the cartridge. Such a mobile system may have one degree of freedom moving frontwards and rearwards. For doing the homing of the movement there may be fixed, digital optical sensor elements and the mobile part, e.g., the maintenance cartridge, may comprise flags 56 to indicate its position. Examples may use a fixed sensor element 54 to collect the signal of the waste level in addition to the position of the cartridge. The sensor element 54 may be implemented as a digital sensor, but the length of the flags may be different in size and/or length, so that it is possible to know which flag is sensed and/or to account for the distance moved by the maintenance cartridge with the optical sensor 54. The flag may float over the waste, rotating, making the flag 22 to protrude from the maintenance cartridge. This flag may be tapered, so that the sensor sees a different length depending on the degrees of rotation of the flag, allowing the printer to know the actual level of the waste.
To develop an analog measure of the waste level, a tapered flag may be used, so that as it rotates, the length increases. When moving the maintenance cartridge, the time which the flag blocks the optical sensor 54 may increase as the length of the flag 22 outside of the cartridge increases. This can be compared to a fixed length reference flag, such as flags 56. To characterize the system, the flag length can be measured with waste at different levels and a relation of waste level versus a length may be developed and stored in the printhead cleaning system 40.
Examples allow for directly measuring accumulated ink waste with low-cost concepts. Further, examples allow the system to avoid suffering from sticking effects of a level sensor due to contact with waste. Alternatively or in addition, examples may allow the system to have a continuous measure of the waste level using a simple optical sensor. Examples directly measure the waste with a floating flag. To avoid the floater sticking to the waste and becoming submerged, examples comprise a mechanical actuator to move the floater every now and then to avoid the gluing and the sticking. The floater floating off of the waste may cause it to rotate and this rotation can make a flag protrude from the maintenance cartridge. The shape of this flag may present the sensor with a different length depending on the degrees of rotation of the flag. This allows to know the level of the waste continuously. By knowing the level of the waste continuously, leakage of the waste in a servicing system may be prevented in a low-cost and direct way. The waste accumulation may be based on different factors such as a percentage of ink loss in aerosol during firing, a temperature, atmospheric pressure, humidity, movement of the waste and/or air flowing over the waste. Examples thus provide for a low-cost waste level sensor in servicing the mobile systems.
When referring again to the printhead cleaning or maintenance system 40 described in connection with
Although the flag 22 may be arranged or oriented so as to face the sensor element 54 with a thin side of the flag 22, see, for example,
All of the features disclosed in the specification including any accompanying claims, abstract and drawings, and/or all the features of any method or progress described may be combined in any combination including any claim combination, except combinations where at least some of such features are mutually exclusive. In addition, features disclosed in connection with a system may, at the same time, present features of a corresponding method, and vice versa.
Each feature disclosed in the specification including any accompanying claims, abstract and drawings may be replaced by other features serving the same, equivalent or a similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example of a generic series of equivalent or similar features.
The foregoing has described the principles, examples and modes of operation. However, the teaching herein are not be construed as being limited to the particular examples described. The above-described examples are to be regarded as illustrative rather than restrictive, and it is to be appreciated that variations may be made in those examples without departing from the scope of the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2018/064551 | 12/7/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/117272 | 6/11/2020 | WO | A |
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Number | Date | Country | |
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20210347177 A1 | Nov 2021 | US |