Printers include a number of different rollers and roller assemblies for performing a variety of tasks and functions. Most basically, these sorts of devices and assemblies are utilized to advance the print media (e.g., paper) through the printer and, in some cases, condition the print media for printing or finishing operations.
Various examples are described below referring to the following figures:
In the figures, certain features and components disclosed herein may be shown exaggerated in scale or in somewhat schematic form, and some details of certain elements may not be shown in the interest of clarity and conciseness. In some of the figures, in order to improve clarity and conciseness, a component or an aspect of a component may be omitted.
In the following discussion and in the claims, the terms “including” and “comprising” are used in an open-ended fashion, and thus should be interpreted to mean “including, but not limited to . . . .” Also, the term “couple” or “couples” is intended to be broad enough to encompass both indirect and direct connections. Thus, if a first device couples to a second device, that connection may be through a direct connection or through an indirect connection via other devices, components, and connections. In addition, as used herein, the terms “axial” and “axially” generally refer to positions along or parallel to a central or longitudinal axis (e.g., central axis of a body or a port), while the terms “lateral” and “laterally” generally refer to positions located or spaced to the side of the central or longitudinal axis.
As used herein, including in the claims, the word “or” is used in an inclusive manner. For example, “A or B” means any of the following: “A” alone, “B” alone, or both “A” and “B.” In addition, when used herein including the claims, the word “generally” or “substantially” means within a range of plus or minus 20% of the stated value. As used herein, the terms “downstream” and “upstream” are used to refer to the arrangement of components and features within a printer with respect to the “flow” of print media through the printer during a printing operation. Thus, if a first component of a printer receives print media after it is output from a second component of the printer during a printing operation, then the first component may be said to be “downstream” of the second component and the second component may be said to be “upstream” of the first component.
As previously described, printers include a number of roller assemblies for advancing print media therethrough during printing operations. In some of these roller assemblies, lubricant is used to facilitate operation (e.g., rotation) of the roller(s) therein. One example of a such a roller assembly is a heated pressure roller assembly commonly used within an inkjet printer. Upon initial startup of a printer (e.g., such as when a print command is received from a computing device), the lubricants of such a roller assembly may be at a relatively low temperature, and thus may be relatively viscous, such that the input torque used to drive rotation of the rollers may be relatively high. This increased torque may cause damage or increased wear to the roller drivers (e.g., motors) or other components within the roller assembly, thereby ultimately resulting in a decreased service life for such components. This issue is further exacerbated by a desire within the printing industry to maximize the speed that printers complete a printing operation, since this assumes the roller assemblies within the printer initiate operation relatively quickly after receipt of the initial print command.
One solution to these issues is to utilize more robust (and therefore more expensive) components within the printer roller assemblies that may withstand higher torque loads during operation. However, market considerations fuel the need to decrease the purchase price for printers, and this frustrates the ability of printer manufacturers to simply overdesign the roller assemblies within the printer to withstand such enhanced loads. Accordingly, examples disclosed herein include roller assemblies (e.g., such as heated pressure roller assemblies) for use within a printer and operation procedures therefor that minimize the loads placed on the roller assembly while also minimizing the time to initiate a printing operation. Thus, through use of the example roller assemblies disclosed herein (including operational procedures disclosed therefor), a printer manufacturer may utilize less robust components within the roller assemblies of the printer so as to produce a printer that has both an acceptable service life and purchase price.
Referring now to
Storage area 20 is a compartment or tray that is sized and arranged to hold pages of print media 50, so that the print media 50 may be accessed by printer 10 to perform printing operations (therefore in some examples, storage area 20 may be referred to as a storage tray). Holding area 30 is “downstream” from the storage area 20, in that print media 50 is advanced from storage area 20 to holding area 30 during a printing operation. Holding area 30 is to receive and hold print media 50 therein until printer 10 is able and ready to receive print media into printing assembly 40 and other assemblies that are downstream from holding area 30 (e.g., HPR assembly 100). Thus, holding area 30 includes rollers that are arranged to contact and hold print media 50 within area 30 and are controllable to selectively advance print media 50 toward downstream assemblies (e.g., printing assembly 40, HPR assembly 100, etc.). To illustrate this, holding area 30 is depicted with a pair of rollers 32, 34 that contact and capture print media 50 therebetween (although it will be appreciated that the arrangement and number of the rollers or other print media contact components within holding area 30 will vary widely in different examples). When a determination is made to advance print media 50 toward printing assembly 40 (e.g., by controllers associated with printer 10), one or both of rollers 32, 34 are rotated to thereby facilitate and drive the advance of the print media 50 toward printing assembly 40 and HPR assembly 100 (in addition to any other assemblies that may be disposed within printer 10 that are downstream of holding area 30).
Printing assembly 40 is an assembly (or collection of assemblies) within printer 10 that is to affix or print an image on print media 50 as it is advanced therethrough. Printing assembly 40 may generally employ any suitable printing technique, such as, for example, inkjet printing, laser printing, phase-change printing, dye-sublimation printing, thermal printing, impact printing, etc. In this example, printing assembly 40 is an inkjet printing assembly that is arranged to fix or dispose an image on the print media 50 by propelling small drops (i.e., droplets) of liquid ink onto the surface of the print media 50 from ink cartridges (not shown). Once print media 50 has the desired image affixed to it with printing assembly 40, it is advanced (either directly or indirectly) to HPR assembly 100.
HPR assembly 100 generally serves to condition the print media 50 following the exit of the print media 50 from printing assembly 40. For example, HPR assembly 100 applies heat to the print media 50 in order to partially or completely dry ink that is applied to the print media 50 within printing assembly 40. The specific components of HPR assembly 100 (and their function) will now be described in more detail below.
Referring now to
Belt 120 is a continuous loop of suitable material (such as, for example, a metallic material coated in a perfluoroalkoxy polymer resin) that is disposed across platen 122 within HPR assembly 100 such that belt 120 is caught or pinched between pressure roller 110 and platen 122 during operations. As a result, when pressure roller 110 is rotated about axis 115a in the manner described above, belt 120 is also rotated generally about an axis 120a that is parallel to and laterally spaced from axis 115a. As a result, when roller 110 is rotated about axis 115a in a first direction 130 (which is shown as a counterclockwise rotation in
As belt 120 is rotated about axis 120a by pressure roller 110 as previously described above, belt 120 slides against platen 122. Platen 122 includes a plurality of grooves or channels 121 that house or contain lubricant (e.g., grease, oil, etc.) therein. As a result, during the above described rotation of pressure roller 110 and belt 120, the lubricant is drawn out of channels 121 and is disposed between belt 120 and platen 122 to lubricate the sliding engagement between belt 120 and platen 122. While not specifically shown, a lubricant injection or supply system may also be included within printer 10 that actively or passively provides additional (or makeup) lubricant to channels 121 or between platen 122 and belt 120 so that there is a sufficient amount lubricant between platen 122 and belt 120 during printing operations.
Referring still to
Driver 116 is coupled to shaft 115 and thus drives rotation of shaft 115 and pressure roller 110 about axis 115a. Driver 114 includes an output shaft 113 that is coupled to a pressure adjustment assembly 118 (or more simply pressure assembly 118) that applies an adjustable pressure to roller 110 along an axis 111 that extends perpendicularly or orthogonally to axis 115a. Thus, driver 114 applies an adjustable force to pressure roller 110 that translates to an adjustable pressure applied by pressure roller 110 to belt 120 and platen 122 via pressure assembly 118, during printing operations.
In this example, driver 114 is to rotate shaft 113 about axis 111, and therefore, pressure assembly 118 may comprise any suitable device or assembly to convert a rotation of shaft 113 about axis 111 into an axial movement or force along axis 111. In particular, in this example, pressure assembly 118 includes a cam assembly 119, and a biasing member 117. In this example, biasing member 117 comprises a linear spring that applies a varying spring force along axis 111 due to relative axial displacement of the terminal ends of member 117 along axis 111. Cam assembly 118 includes cams (not specifically shown), that are rotatable relative to one another about axis 111 to thereby translate one terminal end of biasing member 117 relative to the other terminal end thereof. Specifically, in this example, rotation of shaft 113 about axis 111 causes the cams of cam assembly 119 to rotate relative to others of the cams within cam assembly 119 about axis 111. This relative rotation of the cams in assembly 119 causes a change in an axial length of cam assembly along axis 111, which in turn translates one terminal end of biasing member 117 relative to the other terminal end thereof along axis 111. Therefore, rotation of shaft 113 about axis 111 causes biasing member 117 to apply a changing (or adjustable) biasing force to pressure roller 110 (either directly or indirectly) along axis 111.
It should be appreciated that adjustable pressure assembly 118 may include any suitable components to facilitate the adjustable axial force as described above (and may therefore not include cam assembly 119 or spring 117 as described above). In addition, it should also be appreciated that in other examples, driver 114 may be arranged to translate shaft 113 along axis 111 (e.g., reciprocate), and therefore, adjustable pressure assembly 118 may be omitted in these examples.
Referring still to
Heater 124 may comprise any suitable device (or devices) that output heat energy 128 that may be applied to belt 120 during operations. In addition, heater 124 may apply heat energy to belt 120 via any of radiative, convective, or conductive heat transfer modalities. In this example, heater 124 comprises a halogen lamp that applies heat to belt 120 via radiative (and potentially convective) heat transfer. A temperature sensor 126 is also included within HPR assembly 100 and is to sense the temperature of belt 120 (or a section or length of belt 120) during operations. Heat sensor 126 may comprise any suitable device for measuring or sensing heat on a surface, such as, for example, a thermocouple, thermistor, etc. In this example, heat sensor 126 comprises a thermistor.
HPR assembly 100 also includes a controller 150 coupled to each of the drivers 114, 116 of driver assembly 112, heater 124, and temperature sensor 126. Generally speaking, controller 150 receives signals from heat sensor 126, and controls the operation of drivers 114, 116, and heater 124 during operations of printer 10. Controller 150 may be a dedicated controller for HPR assembly 100 or may be included within a central controller or control assembly for printer 10. In this example, controller 150 is a dedicated controller for HPR assembly 100 and is able to communicate with other controllers or control assemblies within printer 10 (e.g., such as those that facilitate operation of printer assembly 40, as well as components within holding area 30 and storage area 20). The specific component and functions of controller 150 will now be described in detail below with continued specific reference to
In particular, controller 150 may comprise any suitable device or assembly which is capable of receiving an electrical or mechanical signal and transmitting various signals to other devices (e.g., drivers 114, 116, heater 124, sensor 126, etc.). In particular, as shown in
The processor 152 (e.g., microprocessor, central processing unit, or collection of such processor devices, etc.) executes machine-readable instructions 155 provided on memory 154, and upon executing the machine-readable instructions 155 on memory 154 provides the controller 150 with all of the functionality described herein. The memory 154 may comprise volatile storage (e.g., random access memory), non-volatile storage (e.g., flash storage, read only memory, etc.), or combinations of both volatile and non-volatile storage. Data consumed or produced by the machine-readable instructions 155 can also be stored on memory 154.
Controller 150 is coupled or linked to each of the drivers 114, 116, temperature sensor 126, and heater 124 by a plurality of conductors 158, which may comprise any suitable conductive element for transferring power and/or control signals (e.g., electrical signals, light signals, etc.). For example, in some examples, conductors may comprise conductive wires (e.g., metallic wires), fiber optic cables, or some combination thereof. In other examples, controller 150 is to communicates with each of the drivers 114, 116, temperature sensor 126, and heater 124 via wireless connections (e.g., WIFI, BLUETOOTH®, near field communication, infrared, radio frequency communication, etc.).
During operations, controller 150 actuates drivers 114, 116 to rotate shafts 113, 115, respectively to facilitate rotation of roller 110 and belt 120 and to urge pressure roller 110 into engagement with belt 120 and platen 122 as previously described. In addition, controller 150 actuates heater 124 to emit heat energy 128 to belt 120. Further, controller 150 actuates temperature sensor 126 to take readings or measurements of the temperature of belt 120 and to receive output signals (which may be referred to herein as temperature signals) from sensor 126 that include or are indicative of the temperature sensed or measured by sensor 126.
Referring again to
Referring now to
As shown in
Returning to
Method 200 further includes sensing that a temperature of the belt is greater than or equal to a first temperature threshold at 215. In some examples, the first temperature threshold is chosen to ensure a minimum temperature (and thus viscosity) of lubricant disposed between the belt and a belt platen (e.g., platen 122) to maintain torque loads for driving rotation of the pressure roller (e.g., pressure roller 110) at acceptable levels. As a result, in some examples, the first temperature threshold may vary depending on the composition of the lubricant used, as well as the type, size, and properties of the belt, heater, platen, etc. Specifically, in some examples, the first temperature threshold may equal approximately 50° C. When applying box 215 to the example of
Returning again to
Returning again to
Referring still to
Therefore, through use of method 200, the pressure applied by a pressure roller to a belt of a roller assembly (e.g., such as a heated pressure roller assembly 100) of a printer and the release timing of the print media to the roller assembly may be directly tied to the temperature of the belt. As a result, both the torque to drive rotation of the pressure roller and belt and the time to advance print media through the printer may be optimized (e.g., minimized). In addition, it should be appreciated that the application of heat at box 312 increases the belt temperature from an initial or starting temperature to the first temperature threshold at 318, 320 and then subsequently to the second temperature threshold at 330. In some examples, the increase of the belt temperature as a result of the heat applied at box 312 to the first temperature threshold and then the second temperature threshold is continuous (i.e., the temperature of the belt continuously increases from the initial temperature to the first temperature threshold and then to the second temperature threshold).
Referring now to
Initially, method 300 includes applying a first pressure to a belt (e.g., belt 120) of a roller assembly (e.g., HPR assembly 100) with a pressure roller (e.g., pressure roller 110) at 302 and rotating the pressure roller at a first speed at 304. The “first pressure” and the “first speed” of boxes 302 and 304 respectively, correspond with the “first pressure” and “first speed” of boxes 210 and 205 of method 200, previously described (see
Referring still to
If, on the other hand, the determination at 306 is that the belt speed is indeed greater than a minimum speed, then method 300 progresses to apply heat to the belt at 312. The combination of determinations 306, 308 and boxes 310, 312 help to ensure that heat is not applied to the belt until it is determined that the belt is properly rotating, so that an overheating of one portion of the belt is avoided. For example, referring specifically again to the example of
Returning again to
Referring again to
Next, method 300 includes a determination at 322 as to whether the pressure applied to belt (i.e., the “belt pressure” in
If it is determined that the belt pressure is not equal to the second pressure in 322 (i.e., the determination at 322 is “no”), then it is determined at 324 whether a belt pressure timer has expired. For example, in the example of
By contrast, if it is determined at 322 that the belt pressure is equal to the second pressure, then method progresses to 328 where print media (e.g., print media 50) is held within a holding area of the printer. For instance, referring specifically to the example of
Referring again to
Therefore, through use of method 300, the pressure applied by a pressure roller to a belt of a roller assembly (e.g., such as a heated pressure roller assembly 100) of a printer and the release timing of the print media to the roller assembly may be directly tied to the temperature of the belt. As a result, both the torque to drive rotation of the pressure roller and belt and the time to advance print media through the printer may be optimized (e.g., minimized).
The above discussion is meant to be illustrative of the principles and various examples of the present disclosure. Numerous variations and modifications will become apparent to those skilled in the. It is intended that the following claims be interpreted to embrace all such variations and modifications.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2018/036785 | 6/8/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/236111 | 12/12/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
9146509 | Sato | Sep 2015 | B2 |
9329538 | Koda et al. | May 2016 | B2 |
9483002 | Hazeyama et al. | Nov 2016 | B2 |
20100290796 | Sato | Nov 2010 | A1 |
20110135355 | Baba | Jun 2011 | A1 |
20120093547 | Baba | Apr 2012 | A1 |
20120301161 | Fujimoto | Nov 2012 | A1 |
20130223903 | Matsuura | Aug 2013 | A1 |
20140064763 | Watanabe | Mar 2014 | A1 |
20170185013 | Minagawa et al. | Jun 2017 | A1 |
20170219973 | Hadano | Aug 2017 | A1 |
20170242376 | Tsujibayashi et al. | Aug 2017 | A1 |
Number | Date | Country |
---|---|---|
107272384 | Oct 2017 | CN |
2008102464 | May 2008 | JP |
2009300959 | Dec 2009 | JP |
2017122899 | Jul 2017 | JP |
Number | Date | Country | |
---|---|---|---|
20210114383 A1 | Apr 2021 | US |