In some printing apparatuses, images are formed on substrates using a marking material. Such printing apparatuses can include a belt that defines a nip. Substrates are fed to the nip and subjected to processing conditions to fix the marking material onto the substrates.
It would be desirable to provide apparatuses useful in printing and methods that can strip substrates from surfaces effectively.
Apparatuses useful in printing, fixing devices and methods of stripping substrates from surfaces in apparatuses useful in printing are provided. An exemplary embodiment of the apparatuses useful in printing comprises a first member including a first surface; at least one heating element for heating the first surface of the first member; a second member including a second surface forming a nip with the first surface, the nip including an inlet end at which a substrate enters the nip and an outlet end at which the substrate exits from the nip; and an air knife disposed downstream from the outlet end of the nip and extending along an axial direction of the first member, the air knife including a first end, a second end opposite to the first end and a plurality of axially-spaced nozzles disposed between the first end and second end; and at least one gas inlet through which gas is supplied to the air knife. The nozzles are oriented to eject the gas toward the first surface downstream from the outlet end of the nip to facilitate stripping of the substrate from the first surface. The air knife has a configuration and is positioned proximate to the nip such that the substrate does not contact the air knife after exiting the outlet end of the nip when the nozzle gas ejection is ON or OFF.
The disclosed embodiments include an apparatus useful in printing. The apparatus comprises a first member including a first surface; at least one heating element for heating the first surface of the first member; a second member including a second surface forming a nip with the first surface, the nip including an inlet end at which a substrate enters the nip and an outlet end at which the substrate exits from the nip; and an air knife disposed downstream from the outlet end of the nip and extending along an axial direction of the first member, the air knife including a first end, a second end opposite to the first end and a plurality of axially-spaced nozzles disposed between the first end and second end; and at least one gas inlet through which gas is supplied to the air knife. The nozzles are oriented to eject the gas toward the first surface downstream from the outlet end of the nip to facilitate stripping of the substrate from the first surface. The air knife has a configuration and is positioned proximate to the nip such that the substrate does not contact the air knife after exiting the outlet end of the nip when the nozzle gas ejection is ON or OFF.
The disclosed embodiments further include a fixing device for fixing marking material on substrates. The fixing device comprises a first member including a first surface; at least one heating element for heating the first surface; a second member including a second surface forming a nip with the first surface, the nip including an inlet end at which a substrate enters the nip and an outlet end at which the substrate exits from the nip; and an air knife disposed downstream from the outlet end of the nip and extending along an axial direction of the first member. The nozzles are oriented to eject the gas toward the first surface downstream from the outlet end of the nip to facilitate stripping of the substrate from the first surface. The air knife has a configuration and is positioned proximate to the nip such that the substrate does not contact the air knife after exiting the outlet end of the nip when the nozzle gas ejection is ON or OFF.
The disclosed embodiments further include a method of stripping substrates from a surface in an apparatus useful in printing. The method comprises feeding a substrate having marking material thereon to an inlet end of a nip formed by a first surface of a first member and a second surface of a second member, the substrate contacting the first surface and the second surface at the nip; heating the first surface of the first member; supplying gas to at least one gas inlet of an air knife disposed downstream from an outlet end of the nip and extending along an axial direction of the first member, the air knife including a first end, a second end opposite to the first end and a plurality of axially-spaced nozzles disposed between the first end and second end; and optionally ejecting the gas toward the first surface downstream from the outlet end of the nip to facilitate stripping of the substrate from the first surface after exiting the nip at the outlet end, the air knife having a configuration and being positioned proximate to the nip such that the substrate does not contact the air knife after exiting the outlet end of the nip when the nozzle ejects the gas or when the nozzle does not eject the gas.
Apparatuses useful in printing, fixing devices and methods of stripping substrates in apparatuses useful in printing are provided. Embodiments of the apparatuses are constructed to allow different types of marking material to be treated on different types of substrates. Embodiments of the apparatuses include a belt. The belt can be heated to supply thermal energy to substrates that contact the belt. Embodiments of the apparatuses are constructed to allow different types of substrates to be stripped from the belt.
The apparatuses useful in printing and fixing devices include an air knife. The air knives emit a suitable gas, such as air, to facilitate stripping of substrates from the belt after the substrates pass through the nip. Embodiments of the air knife are configured to have a sufficiently-low profile to not intrude into the exit path of different types of substrates. Embodiments of the air knives can also provide uniform air flow ejection performance from all nozzles.
Embodiments of the apparatuses useful in printing may include a printing apparatus, such as shown in
The apparatuses useful in printing can use various types of solid and liquid marking materials, including toners and inks (e.g., liquid inks, gel inks, heat-curable inks and radiation-curable inks), and the like. The apparatuses can use various thermal, pressure and other process conditions to treat marking materials on substrates.
As shown in
The fuser roll 208, external roll 210 and internal rolls 212, 214 include internal heating elements 226, 228, 230 and 232, respectively, connected to a power supply 234. The power supply 234 is connected to a controller 236 that controls the supply of voltage to the heating elements 226, 228, 230 and 232, to heat the belt 202 to the desired temperature.
The fuser 200 further includes an external pressure roll 240 having an outer surface 242. The outer surface 242 is shown engaging the outer surface 206 of the belt 202 to form a nip 244. Embodiments of the pressure roll 240 can include a core, an inner layer overlying the core, and an outer layer overlying the inner layer and forming the outer surface 242. The core can be comprised of aluminum, steel or the like, the inner layer of an elastomeric material, such as silicone rubber, or the like, and the outer layer of a low-friction polymer, such as polytetrafluoroethylene (Teflon®), or the like.
Embodiments of the belt 202 can include two or more layers. For example, the belt 202 can include a base layer forming the inner surface 204, an intermediate layer on the base layer, and an outer layer on the intermediate layer and forming the outer surface 206. In an exemplary embodiment, the base layer can be comprised of a polymer, such as polyimide, or the like; the intermediate layer of silicone, or the like; and the outer layer of a polymer, such as a fluoroelastomer sold under the trademark Viton® by DuPont Performance Elastomers, L.L.C., polytetrafluoroethylene, or the like.
In embodiments, the belt 202 can have a thickness of about 0.1 mm to about 0.5 mm, such as less than about 0.2 mm. For example, the belt 202 can include a base layer having a thickness of about 50 μm to about 100 μm, an intermediate layer having a thickness of about 100 μm to about 500 μm, and an outer layer having a thickness of about 20 μm to about 40 μm. The belt 202 can typically have a width dimension along the longitudinal axis of the fuser roll 208 of about 350 mm to about 450 mm.
As shown in
In other embodiments of the fixing devices, the stripping device 260 can comprise a stripping device as disclosed in U.S. patent application Ser. No. 12/352,250 filed on Jan. 12, 2009 and Ser. No. 12/363,724 filed on Jan. 31, 2009, each of which is incorporated herein by reference in its entirety.
In the illustrated embodiment of the fuser 200, the stripping device 260 and air knife 270 both facilitate stripping of substrates from the outer surface 206 of the belt 202.
The belt 302 is located between the outer surface 318 of the fuser roll 308 and the outer surface 342 of the pressure roll 340. A nip 344 is formed between the fuser roll 308 and pressure roll 340. The nip 344 includes a first nip N1 extending between an inlet end, IE, and an outlet end OE1 disposed downstream from the inlet end IE. Substrates are fed to the inlet end IE and exit at the outlet end OE1. At the first nip N1, the belt 302 contacts the outer surface 318 of the fuser roll 308 and the outer surface 342 of the pressure roll 340. The belt 302 diverges from the outer surface 318 of the fuser roll 308 at the outlet end OE1 of the first nip N1. The first nip N1 is a high-pressure region at which thermal energy and pressure are applied to substrates. A marking material, such as toner, can be fixed onto substrates at the first nip N1.
As shown in
The stripping device 360 is located downstream from the outlet end OE2 of the second nip N2. Substrates are stripped from the outer surface 306 of the belt 302 adjacent to the stripping device 360. The stripping device 360 is located sufficiently close to the outlet end OE1 of the first nip N1 to allow substrates to be stripped from the belt 302 shortly after exiting the first nip N1.
In embodiments, the stripping device 360 can include a stripping wire extending along the axial direction of the fuser 300. The stripping wire has a sufficient length to contact the inner surface 304 of the belt 302 across the entire width of the belt 302. The stripping wire is tensioned sufficiently to maintain the belt spaced from the outer surface 318 of the fuser roll 308. The stripping wire produces a stripping force effective to facilitate stripping of substrates from the outer surface 306 of the belt 302 adjacent to the stripping device 360. For a stripping wire having a circular cross-section, decreasing the diameter of the stripping wire increases the magnitude of the stripping force it produces. Thin substrates are typically the most difficult substrates to strip from the belt 302. The stripping wire can have a small diameter to provide a high stripping force to facilitate stripping of such light-weight substrates from the belt 302. In contrast, heavy-weight substrates are typically easiest to strip. In embodiments, the stripping wire can have a larger diameter that produces a lower stripping force to facilitate stripping of such heavy-weight substrates from the belt 302.
The exemplary air knife 370 shown in
In the air knife 370, the nozzles 372 each extend in the radial direction through the wall between the outer diameter 374 and inner diameter 376. The air knife 370 can typically include 3 to about 16 or more nozzles to provide the desired gas flow characteristics along the width of the belt 302. The nozzles 372 are typically aligned with each other along the length of the air knife 370. The nozzles 372 can be substantially equidistantly spaced from each other along the length of the air knife 370. In other embodiments, the nozzles 372 can have other patterns to provide other desired gas flow characteristics at one or more locations along the width of the belt 302. The nozzles 372 can typically have a diameter of about 0.5 mm to about 1.5 mm. The nozzles 372 can typically have the same, or approximately the same, cross-sectional flow area (e.g., diameter) to provide substantially equal air flow from each of the nozzles 372.
Other embodiments of the air knife can have a different cross-sectional shape than the circular shape shown in
For example,
An air knife 570 is disposed external to the belt 502. The air knife 570 has a circular cross-section like the air knife 370 shown in
As shown in
However, it has been noted that such heavier un-coated and coated substrates may not properly exit fusers that include a bulky air knife with a large cross-section. Such substrates can collide with the air knife and consequently become damaged and also produce jams.
In contrast to the air knife 770 having a large cross-section, each of the air knives 370, 470 and 570 shown in
Embodiments of the low-profile air knives, such as air knives 370, 470 and 570, allow an independent baffle to be used at an optimal location in apparatuses useful in printing. The independent baffle can be a flat surface, a flat surface with ridges, or the like. The ridges can limit air speed by providing a minimum exit area for the air flow. Consequently, exiting media will experience a limited Bernoulli effect (i.e., a reduction of the static pressure in the presence of moving air). If the air speed on the top of a sheet is larger than on the bottom of the sheet, then a vacuum is possible due to the existence of a differential static pressure, as the static pressure is lower on the side of the sheet with the highest air speed.
Other embodiments of the fixing devices do not include a stripping element (such as one of the stripping devices 260, 360 and 560) other than the air knife to assist stripping of substrates from a belt.
Embodiments of the air knives can be used in fixing devices including belts and having a different construction than the fuser 200 shown in
Embodiments of the stripping wires can also be used in apparatuses useful in printing that do not include a belt (such as the belt 202, 302 or 502), but which include opposed rolls that form a nip.
Embodiments of the low-profile air knives, such as the air knives 370, 470, 570 and 970, can also provide cost savings by being manufactured at low manufacturing costs as compared to more air knives with more complicated structures.
For example, embodiments of the air knife having a circular cross-section, such as the air knives 270, 370 and 570, can be produced from a hollow tube of a suitable metal or plastic material. The nozzles can be formed through the wall of the tube using any suitable drilling technique that forms holes with the desired shape and tolerances. The thickness of the wall of the tube is sufficient to provide the desired strength and to allow the nozzles to be formed in it.
The gas-ejection performance of embodiments of the low-profile air knives can be improved by utilizing the following exemplary design considerations. For plenum pressure uniformity (which ensures nozzle performance uniformity), the combined cross-sectional area of the gas inlets is at least ten times greater than the total cross-sectional area of all of the nozzles. For an exemplary embodiment of an air knife having a circular cross-section (such as shown in
The wall thickness of the tube of the air knife is desirably about three times the diameter of the nozzles. For a nozzle diameter of 0.75 mm, a wall thickness of the tube of about 2.3 mm is desirable. It is also desirable that the surfaces defining the nozzles be smooth.
Based on the these considerations, a hollow tube having an inner diameter of about ⅜ inch (about 9.5 mm), and a wall thickness of about 3/32 inch (about 2.4 mm) with sixteen equally-spaced nozzles each having a diameter of 0.75 mm diameter can provide high gas flow uniformity in a low-profile air knife at a low cost.
It will be appreciated that various ones of the above-disclosed, as well as other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also, various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art, which are also intended to be encompassed by the following claims.
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