The present invention relates to method and apparatus for sublimation transfer using a long, tunnel furnace.
Sublimation transfer requires pressing a sublimation transfer image against a surface while heating the surface and image to a temperature high enough to cause the sublimation transfer image to sublimate and transfer to the surface. One approach to achieve this sublimation transfer is to have pressing devices shaped to conform to the product shape press the sublimation transfer image against the product while heating the product and image. Arrangements for transferring images to a coffee mug are described U.S. Pat. No. 5,755,921 to Christensen and U.S. Pat. No. 5,944,931 to Cranford. These patents place the assembled pressing device, image and product in an oven and remove them after each sublimation transfer occurs. These one-at-a-time approaches are inefficient for handling large numbers of products because the time to load, unload, heat and cool each product is extensive and hence the accompanying cost is high. There is thus a need for an improved sublimation transfer process and apparatus.
Another approach to achieve this transfer is have sublimation transfer images held against the product surface by stretching elastomeric sheets to press the images against the product surface. The assembly is heated in a furnace, causing the images to transfer to the product surface under pressure provided by stretching the elastomeric sheets around the products to cause sufficient pressure for sublimation transfer. The elastomeric sheets and transfer process are as generally described in U.S. Pat. No. 8,002,931 to Wang et al. Sublimation transfer has used a mesh belt conveyor to move products along a long tunnel. These assemblies may be placed in the bottom of an oven or furnace, or they may be placed on an endless, moving conveyor belt that passes through a furnace to achieve the heating and sublimation transfer. But the wrapping of stretched material does not conform to the configuration of rapidly changing surfaces and each product is individually wrapped. This approach is thus inefficient for handling large numbers of products because the time to load, unload, heat and cool each product is extensive and hence the accompanying cost is high. There is thus a need for an improved sublimation transfer process and apparatus.
Vacuum has been used to draw flexible membranes against a surface in order to apply the pressure for sublimation transfer, with U.S. Pat. Nos. 6,814,831 and 7,810,583 describing such systems. But the vacuum systems use single trays that are immovable or reciprocate into or out of a heating chamber, limiting the use of the apparatus and quantities of resulting imaged products. There thus remains a need for an improved method and apparatus to efficiently apply sublimation images to products.
In one embodiment, the present invention provides a sublimation furnace with a first endless conveyor belt extending along a first axis through the furnace. The furnace has a chamber extending above and along that first conveyor belt. Vacuum trays are placed on the first belt where the trays have products abutting sublimation images to be transferred to the product as the trays pass through the furnace. The furnace has a first sidewall with a slot extending along the sidewall and along the first conveyor belt. A second endless conveyor belt extends along but offset from the first axis. A plurality of vacuum pumps are each connected to the second conveyor belt and move with that belt. Each vacuum pump is connected by a hose passing through the slot during use of the furnace to a different vacuum tray on the first conveyor in order to evacuate the vacuum trays and press the images against the product for sublimation transfer.
In a further embodiment, there is advantageously provided a furnace having a conveyor belt for heating a product on the belt as the product moves through the furnace on the belt. The furnace includes a first endless conveyor belt extending along a first axis. The furnace has a chamber extending above and along a first length of the first conveyor belt. The furnace chamber has an inlet end and an outlet end through which the first conveyor belt passes. The furnace also has heaters and a first side wall extending along the first length of the first conveyor. A slot extends through the first side wall and further extends along the first conveyor. The furnace has a second endless conveyor belt extending along but offset from the first axis. The furnace has a plurality of vacuum pumps, each connected to the second conveyor belt and moving with that second conveyor belt. Each vacuum pump has a vacuum hose connected to it with the hose passing through the slot during use of the furnace and pump.
In further variations of this further embodiment, the furnace has a power strip extending along a length of the second conveyor belt. The power strip has a first elongated electrically conductive strip carrying electrical current along that length of the second conveyor belt during use. Each of the plurality of vacuum pumps has an electrical connection resiliently urged into electrical contact with that first conductive strip during use. A vacuum housing may extend along and enclose the second conveyor belt and the power strip. The first and second conveyor belts may be driven by a common drive shaft or by separate shafts rotating about a common axis.
In further variations, the slot may have a longitudinal length with two opposing sides and a vertical height between those two sides, and may have at least one flexible strip of material extending from one side of the slot toward the other side of the slot. The material advantageously has sufficient flexibility so each hose may push the material aside as the hose moves along the length of the slot. The flexible strip of material may include first and second strips of material each extending from a different side of the slot and extending toward the other strip of material to block the slot.
In further variations of this further embodiment, a plurality of vacuum trays are provided, each in fluid communication with a different one of the vacuum pumps through the hose associated with each vacuum pump. Each hose advantageously has a quick release coupling to releasably disconnect the hose from one of the vacuum pump or tray. The vacuum tray may advantageously include an enclosure with a bottom and sidewalls, a perforated support plate, a mounting boss, a product on that boss, a sublimation transfer image abutting the product, a flexible sealing sheet overlapping the product and image and at least a portion of the support plate, and a frame configured to hold the sealing sheet against the support plate.
In still further variations, a power strip extends along a length of the second conveyor belt. The power strip advantageously has a first elongated electrically conductive strip carrying electrical current along that length of the second conveyor belt during use. Each vacuum pump advantageously has a resilient electrical connection contacting the power strip and that first conductive strip during use. A plurality of the vacuum trays are each placed in fluid communication with a different one of the vacuum pumps through the hose associated with that different one of the vacuum pumps, with each hose having a quick release coupling to releasably connect the hose from one of the vacuum pump or tray.
There is also provided a method of sublimation transfer using a vacuum tray having a sublimation transfer image and product which are located between a sealing sheet and a bottom of the tray. The method placing a plurality of the vacuum trays on a first endless conveyor belt moving through a heated furnace. The furnace has an inlet end and an outlet end. Each vacuum tray has a separate fluid connection located to evacuate air from between the sealing sheet and tray bottom, with the tray placing step occurring at the inlet end of the furnace. The method includes placing a separate vacuum pump in fluid communication with the separate fluid connection of a different one of the plurality of vacuum trays. Each of the separate vacuum pumps is connected to and moves with a second endless conveyor belt moving parallel to the first conveyor belt. The method may further include evacuating air from between the sealing sheet and the tray bottom of each tray and pressing the sublimation transfer image against the product with sufficient force to achieve sublimation transfer. The method may also include heating the sublimation transfer image and product to a sublimation transfer temperature for a time sufficient to transfer the image to the product. shutting off the vacuum pump and then releasing the vacuum from the space between the sealing sheet and bottom of the tray. The method may further include removing the vacuum pump from fluid communication with the tray to which the vacuum pump was connected and removing the tray from the first conveyor belt at the outlet end of the furnace.
In further variations, the step of evacuating air may further include activating each vacuum pump at a first predetermined location of the vacuum pump along a length of the second conveyor. The step of shutting off the vacuum pump may include shutting off each vacuum pump at a second predetermined location of the vacuum pump along a length of the second conveyor. The step of placing a separate vacuum pump in fluid communication with the separate fluid connection of a different one of the plurality of vacuum trays advantageously uses a hose for the fluid communication and may also include passing that hose through a slot in the furnace and moving that hose along a length of the slot. The step of placing a separate vacuum pump in fluid communication with the separate fluid connection of a different one of the plurality of vacuum trays may also use a hose with a quick disconnect coupling for the fluid communication. The step of removing the fluid connection between each of the plurality of trays and the vacuum pump to which the tray was connected advantageously includes uses a quick disconnect coupling to disconnect a hose from the vacuum pump from the different vacuum trays
In still further variations, the step of evacuating air from between the sealing sheet and the tray bottom of each tray advantageously includes activating the vacuum pump when the tray is at a first predetermined location of the first conveyor belt relative to the furnace. The step of activating the vacuum pump may include placing the vacuum pump in electrical contact with a power strip extending along a length of the second conveyor belt to place the vacuum pump in electrical communication with a power source. The step of evacuating air from between the sealing sheet and the tray bottom of each tray may include activating the vacuum pump before the tray has entered an actively heated portion of the furnace. The step of shutting off the vacuum pump may include deactivating the vacuum pump when the tray is at a second predetermined location of the first conveyor belt relative to the furnace, with the second predetermined distance being closer to the outlet end of the furnace than the first second predetermined distance. The step of shutting off the vacuum pump may include disconnecting the vacuum pump from electrical contact with the power strip.
These and other advantages and features of the invention will be better appreciated in view of the following drawings and descriptions in which like numbers refer to like parts throughout, and in which:
Referring to
The heating chamber 10 preferably has insulated walls, with
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The length of the electrical power rail 52 may be shorter or longer than the length of the heating chamber 10 as the electrical contact with wires 54 a vacuum need not be maintained during the entire length of the heating chamber 10. Preferably though, the power rail 52 is located so the electrical contacts 54 provide power to the vacuum pump 26 to begin creating a negative pressure in the hose 28 and tray 18 before or upon entry into the heating chamber 10. Preferably, the power rail 52 ends so as to break electrical contact with wires 54 after the tray 18 has been in a heated portion of chamber 10 a time sufficient for tray 10 and products 22 to accept a sublimation image 20 and for that image to cool enough so it will not be distorted by removal of the pressure applied by the vacuum from pump 26 and hose 28. The power rail 52 and resiliently
Referring to
Referring to
For sublimation transfer, the tray 18 typically contains a support plate 70 that may have one or more shaped platens 72 configured to support parts or products 22 that are to receive the sublimation image 20. The support plate 70 may have recesses 69 configured to receive the platens 72, typically with bolts 71 passing through the plate 70 to securely fasten the platen to the plate 70 and allow air passage to the bottom of the platen. The support plate 70 typically conforms to the shape of the tray 18 and has a plurality of holes 74 through the plate to draw a vacuum.
The tray 18 typically has a bottom that is slightly concave or inclined to form a gap between the support plate 70 and the bottom of the tray to make it easier to withdraw all the air from the tray through tube 64. The tube 64 is preferably adjacent the bottom surface of the tray 18. The products 22 may have the dye transfer image applied directly to them by spray, screening, painting or other methods.
Referring to
As the vacuum pump moves on the second conveyor belt 24, the electrical contacts 54 resiliently engage the power strip 52 to activate the pump and withdraw air from beneath the frame 80 and sealing sheet 78, causing the sheet 78 to press the image 20 against the product 22 at up to 14.7 pounds per square inch (psi.). The tray 18 and its contents are heated by heaters 12 (
In some applications, a single hose 28 may be used to connect the vacuum pump 26 and tray 18, but it is preferred to have a hose 28, 28′ on each of those parts with a quick disconnect fitting 82 to releasably connect the hoses. Any conventional quick-disconnect air hose fitting may be used for the fitting 82, and may couple the hoses, or couple either hose 28, 28′ to the vacuum pump or tray associated with the specific hose and fitting being connected. Illustrative quick connections are shown in U.S. Pat. Nos. 4,193,616 and 9,377,145 and include various detent retention mechanisms, rotating interlocking mechanisms and snap fitting mechanisms.
The heating chamber 10 is preferably an elongated furnace similar to existing industrial mesh belt furnaces having an inlet end where trays 18 are placed on the conveyor belt 18 and an outlet end where the trays are removed from the belt after passing through the furnace. Such furnaces are believed available in various lengths and widths, with a width of first conveyor belt 18 of about 0.6 to 0.8 meters being believed suitable, and a length of about 9-12 meters believed suitable. The conveyor advantageously has a mesh belt transport chain, with suitable heaters 12 and fans (not shown) as desired to circulate heated air for uniform heating of the product 22 and images 20, and for blowing cooling air onto the trays, product and images once sublimation transfer is completed.
A separate vacuum pump 26 is preferably in fluid communication with a separate tray 18 and moves generally parallel with the tray, with second conveyor belt 24 supporting the vacuum pumps and first conveyor belt 16 supporting the vacuum trays. The evacuation of air from beneath the sealing sheet 78 allows atmospheric pressure to press the sheet 78 and transfer sheet 76 against the product 22 as the tray moves through the heating chamber 10 with the vacuum being maintained until sublimation transfer has occurred and preferably until the transferred image and the surface of the product 22 in which the image is embedded cool sufficiently so that the image does not distort, after which the vacuum may be released. A suitably flexible sealing sheet allows imaging of parts having various curved contours, including the curved surfaces joining the flatter sides and back of a case for a cell phone.
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The use of a separate vacuum pump 26 or each tray allows a smaller capacity pump to be used, reducing costs and, because the tray 18 allows a smaller area to be evacuated, allows faster application of the clamping force for sublimation once evacuation begins. The movement of the pump 26 simultaneous with the tray 18 allows the localized tray vacuum to be maintained as the tray moves along the length of the oven. The heat loss from the heating chamber may be reduced by providing insulating curtains arising from overlapping a plurality of strips 56, 58 of flexible but insulated and (suitably) temperature compatible material. Similar hanging strips of high temperature compatible, material hanging over the entrance and exit openings of the heating chamber 10 may be used to reduce heat loss through those openings. Similar hanging strips may be used internally to the heating chamber 10, as for example, to separate the heating portion of the conveyor belt 16 from a cooling portion of the chamber. While the reduction in heat loss through the slot 38 is shown as achieved by a “plurality” of separate strips 56, 58 hanging down and/or extending upward across some or all of the slot, a single strip of material could be used as long as it is flexible so as to allow the material to fold back over the slot in the area adjacent the hose 28, 28′ passing through the slot and displacing the strip to allow passage of the hose. A strip sufficiently flexible to allow the strips 56, 58 to bend around the hose and extend across the slot within about 5-10 cm of the hose (measured along the length of the slot) is believed suitable.
There is also provided a method of sublimation coating a product 22 with a sublimation dye image 20, which preferably includes the step of placing the product and dye image 20 (on or off of a transfer sheet 76) in a first vacuum tray 18, preferably on a support plate 70, and covering the image, sheet and product with a sealing sheet 78. A frame 80 urges the sealing sheet 78 against the plate 70 to ensure evacuation of air between the sealing sheet and plate, allowing the atmosphere to press the sheet and image against the product 22. The method includes placing the tray on a first conveyor and removably placing the tray 18 and above described parts in fluid communication with a vacuum pump on a second conveyor moving along a length of the first conveyor. The connection with the tray is located to evacuate the space below the sealing sheet 78 and the vacuum tray 18, the support tray 70 having gas passages extending through it to allow such evacuation. The first and second conveyor belts carry the tray and parts into and through a heating chamber 10. The method includes applying electrical energy to the vacuum pump 26 and activating the pump to evacuate the tray and press the image against the product for sublimation transfer. The heating chamber is preferably selected so the conveyor speed, chamber temperature and chamber length are such as to heat the product 22 and image 20 high enough to achieve sublimation transfer of the image onto and preferably into a surface of the product. After sublimation transfer of the image 20 onto the product 22, the method preferably but optionally includes a step of passively or actively cooling the product, image and supply sheet to a temperature sufficient to prevent running of the dye forming the image 20, and preferably to prevent deformation of the product 20. After sublimation transfer of the image 20 onto the product 22, the power to the pump 26 may be disconnected to release the vacuum and pressure urging the image against the product. When the first conveyor belt 16 carries the first tray 18 and now imaged product 22 out of the heating chamber 10 the first tray is disconnected from the vacuum pump and removed from the first conveyor belt 16, while the vacuum pump continues to circulate with the second conveyor. The frame 80 is released (latches 66a, 66b) and the now imaged parts 22 removed from the first tray. While the first tray 18 is being moved by the first conveyor belt 16, a second tray 18 with second products 22 and second images 20 and second transfer sheet 78 are assembled and connected by second hoses 28, 28′ to a second vacuum pump also connected to the second conveyor belt 24. Thus, a series of products, images, sealing sheets and trays are sequentially processed, allowing a continuous sequence of trays to be connected to dedicated vacuum pumps for evacuation and sublimation transfer of parts having various contours.
The method advantageously includes reducing heat loss by releasably blocking an elongated slot 38 extending along a length of the heating chamber as a connecting vacuum hose passes along the slot. The method preferably includes connecting at least one and preferably a plurality of strips 56, 58 of flexible, high temperature material to extend across part or the entire slot from one or both sides of the slot so as to block the passage of hot air through the slot. The method preferably includes moving the connecting vacuum hose along the slot with the hose pushing the at least one strip or strips of material aside to allow the hose to pass with the at least one strip or strips of material resiliently blocking the slot after passage of the hose. Preferably, the strips extend from opposing sides of the slot but each strip does not extend entirely across the slot so opposing strips cooperate to block the passage of hot gas out of the slot and past the strips. Advantageously, strips of such material hang downward from the top of the entrance and exit of the heating chamber, preferably extending to the first conveyor belt 16. The material forming strips 56, 58 is preferably suitable for use with sublimation temperatures, and may be silicon, rubber, or other suitable elastomers, or it may comprise small diameter bristles (like the bristles of a paint brush) of suitable material.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention in virtually any appropriately detailed structure.
The above description is given by way of example, and not limitation. Given the above disclosure, one skilled in the art could devise variations that are within the scope and spirit of the invention, including various ways of Further, the various features of this invention can be used alone, or in varying combinations with each other and are not intended to be limited to the specific combination described herein. Thus, the invention is not to be limited by the illustrated embodiments. Finally, it should be noted that the above only to illustrate the utility of new technical solutions and are not limitations. Although the system and method are described in detail with reference to the preferred embodiments program, one of ordinary skill in the art should be understood that the present disclosure (for example in the form of kilns, molds and connection type relationship) may be modified or replaced by equivalents without departing from the spirit and scope of the disclosure and/or claims herein.
The application claims the benefit under 35 U.S.C. § 119(e) to Provisional Patent Application No. 62/364,254 filed Jul. 19, 2016, the entire contents of which are incorporated herein by reference.
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