This application relates generally to positive temperature coefficient heater elements, and specifically to additively manufactured positive temperature coefficient heater elements.
Heated tubes or tubes are used in a variety of industries to heat fluid passing through such a vessel and prevent unwanted freezing. In prior art, resistor heaters that are spiral wound around the core of the tube or tube are used to provide heat. Alternatively, heater tapes are wrapped around the core of the tube or tube. These types of heating elements require sensors or thermostats to prevent overheating, or the use of positive temperature coefficient of resistance (PTC) heating material to limit overheating. These types of heating elements can be bulky and require excess space around the tubes, in addition to requiring external control.
In a first embodiment, a heater tube assembly includes a tube, a bus bar network on the tube, a positive temperature coefficient heater on the tube, a closeout adhesive securing the bus bar network and the positive temperature coefficient heater to the tube, and an outer dielectric layer overlaying the bus bar network and the positive temperature coefficient heater. The bus bar network includes one or more layers of a first additively manufactured conductive ink. The positive temperature coefficient heater comprising one or more layers of a second additively manufactured conductive ink. The positive temperature coefficient heater is electrically connected to the bus bar network.
In a second embodiment, a heater tube assembly includes a tube, a bus bar network including at least one hot bus bar and at least one neutral bus bar on the tube, a heater on the tube having a thickness between 0.0001 and 0.010 inches, a closeout adhesive securing the bus bar network and the heater to the tube, and an outer dielectric layer overlaying the bus bar network and the heater. The bus bar network is made of one or more layers of a first additively manufactured conductive ink, and the bus bar network is a geometric pattern selected from the group consisting of a spiraled pattern, a redundant dual-circuit pattern, a crisscross pattern, or combinations thereof. The heater includes a plurality of layers of a second additively manufactured conductive ink, each of the plurality of layers has a thickness of between 1 and 100 microns, and the heater is electrically connected to the bus bar network.
In a third embodiment, a method of making a heater tube assembly includes additively manufacturing one or more layers of a first conductive ink on a tube to create a bus bar, additively manufacturing one or more layers of a second conductive ink on a tube to create a positive temperature coefficient heater overlapping with the bus bar, closing out the bus bar and the positive temperature coefficient heater with an adhesive, and encapsulating the bus bar and the positive temperature coefficient heater with an outer dielectric layer.
Disclosed are flexible printed heating elements made via additive manufacturing with conductive inks. A flexible substrate is used so that the printed heating element can conform to the shape of the component surface to which it is applied. A self-limiting positive temperature coefficient (PTC) heating material is used.
PFA liner 12 is a perfluoroalkoxy alkane liner inside tube 10. PFA liner is an insulating material inside tube 10 that separates heater wires 14 from fluid passing through tube 10. PFA liner 12 electrically and chemically insulates fluid passing through tube 10 from heater wires 14 and braids 16, 18.
Heater wires 14 provide heat to tube 10, and are spiral wound around tube 10. Heater wires 14 can be, for example polyimide-insulated nichrome. Heater wires 14 may also be embedded in a silicone material. Heater wires 14 are joined at the end of tube 10 to allow for electrical connection to both positive (+) and negative (−) wires at that end. In the case of dual element tubes, there can be two sets of wires wound together. Stainless steel braid 16 and aramid fiber braid 18 provide structural support and protection of heater wires 14. The prior art configuration of tube 10 is bulky due to multiple layers of protection and support in the form or braids 16, 18, and the winding of wires 14 around a core material.
Liner 22 rests inside tube 20A for chemical compatibility with the fluid flowing through tube 20A. In some cases, liner 22 is made of a material to allow water potability. Liner 22 can be, for example, a fluoropolymer material (such as polytetrafluoroethylene (PTFE) or perfluoroalkoxy (PFA)), a fluoroelastomer, a silicone, a polyolefin (such as polyethylene or polypropylene), acrylonitrile butadiene rubbers (such as nitrile or NBR), ethylene propylene diene monomer rubbers (such as EPDM), polyurethane (PU), or combinations thereof.
Conductive tube 24A is the structural part of tube 20A through which fluid flows. Conductive tube materials include metals such as stainless steel or titanium. Other types of conductive tube materials include carbon-filled plastics, such as polyetherimide (PEI), polyetheretherketone (PEEK), polyphenylene sulfide (PPS), polyimide (PI), ethylene tetrafluoroethylene (ETFE), polyvinylchloride (PVC), or polyvinylidene difluoride (PVDF) filled with carbon such as carbon black, carbon nanotubes, or carbon fibers.
Inner dielectric 26 isolates conductive tube 24A from bus bar 28 and PTC heater 30. Inner dielectric 26 can be polyimide, polyurethane, silicone, or other materials deemed suitable by a person of skill in the art. If conductive tube 24A is a carbon-filled plastic, then inner dielectric 26 can be the same plastic but un-filled, or glass-filled.
PTC heater 28 is the heating element of heater tube 20. PTC heater 28 is an additively manufactured PTC ink on the surface of inner dielectric 26. PTC heaters are self-regulating heaters that run open loop without any external diagnostic controls. Positive temperature coefficient heaters come to full power and heat up quickly to optimum temperature, but as heat increases, power consumption drops. This dynamic type of heater is effective and time and energy efficient. Thus, PTC heater 28 made with PTC ink does not require an outside temperature control. Examples of PTC inks include DuPont® 7292 from DuPont USA or Henkel® EC1 8060 from Henkel.
The PTC ink of PTC heater 28 is formulated to allow highly detailed precision printing, and maintain a high resistance without bleeding between adjacent additively manufactured lines. The PTC ink is additively manufactured onto inner dielectric 26 through a printing process such as ink-jet, aerosol-jet printing, or other suitable processes.
Typically, ink-jet or aerosol-jet printing can be used to additively manufacture PTC heater 28, depending on the type of PTC ink chosen, desired layer thickness, and dimensions of PTC heater 28. Printing PTC ink may require dilution of the ink to allow precision and prevent print-head clogging. Depending on the specific PTC ink used, the ink may need to be diluted from 1% to 50% with appropriate solvents.
For ink-jet and aerosol-jet methods, the print head should be moveable at least on (x, y, z) axes and programmable with the geometric pattern specific to the component on which PTC heater 28 will be applied. The specific print heat and additively manufacturing method will be dependent on the exact PTC ink formulations and requirements set forth by the manufacturer of the PTC ink. Ink-jet and aerosol-jet printers and printing heads can also be utilized for two dimensional applications, such as printing on a dielectric layer of a non-conductive tube, but ideally can be adapted to enable three dimensional (three dimensional) printing capabilities by attaching the printing heads onto a numerically controlled robotic arm. For example, three dimensional ink-jet and aerosol-jet printing equipment developed by Ultimaker® (three-dimensional ink-jet equipment) or Optomec® (three-dimensional aerosol-jet equipment) can be used. For ink-jet or aerosol-jet methods, the printing head temperatures, flow rates, nozzle sizes are also selected based on the PTC ink being printed, required conductive ink thickness, and substrate to be additive manufactured on. Alternatively, the PTC ink can be deposited or direct printed with extruded ink on the tube using micro-dispensing pumps such as those made by nScrypt®.
The printing is accomplished in an additive manner, meaning the print head takes one or more passes before a desired element resistance is reached in the desired geometric pattern and desired dimensions, which matches the curvature of the component. Depending on the application, two or more, three or more, four or more, or additional passes may be appropriate.
The PTC ink of additively manufactured PTC heater 28 should have a thickness of approximately between 0.0001″-0.010″. Multiple passes are done by the print head when applying the conductive ink. Each layer deposited through individual passes of the print head should have a thickness of approximately 1-100 microns. Multiple passes allows for slow buildup of the PTC ink to the correct resistance and geometric pattern. Additionally, multiple passes allows for tailoring of the PTC ink on certain portions of the component surface. For instance, PTC ink with a lower resistance (e.g., with a higher number of layers) and a greater thickness may be additively manufactured on a first portion of the component compared to a second portion of the component.
After additively manufacturing PTC heater 28, the PTC ink is cured. The curing process of additively manufactured PTC heater 28 depends on the type of PTC ink used. In some instances, the PTC ink will air dry. In other instances, heat, infrared exposure, UV exposure, chemical, or other methods can be used to cure the PTC ink. The PTC ink can be cured (partially or fully) during the printing process, to avoid dripping or smearing of the ink during processing.
Bus bar 30 is also additively manufactured onto the surface of inner dielectric 26. Bus bar 30, made of a conductive ink, provide electrical connection from PTC heater 28 to an outside controller (not pictured). Bus bar 30 can be made of a conductive carbon filled or silver filled ink, such as DuPont® 5205 available from DuPont USA or Henkel® EC1 1010 available from Henkel.
Bus bar 30 is additively manufactured in a similar method to that described with reference to PTC heater 28. Generally, bus bar 30 is additively manufactured on top of and overlapping with portions of PTC heater 28 to create an electrical connection between PTC heater 28 and bus bar 30. Specific geometries of bus bar 30 and PTC heater 28 are discussed with reference to
Closeout adhesive 32 seals and encapsulates PTC heater 28 and bus bar 30. Closeout adhesive 32 is applied on top of both PTC heater 28 and bus bar 30 to secure and protect these components, separating them from the external environment. Closeout adhesive 32 can be, for example, an acrylic or rubber pressure sensitive adhesive, or ethylene-vinyl acetate.
Outer dielectric 34 is applied to printed heater tube 20A after closeout adhesive 32 is cured or dried. Outer dielectric 34 electrically insulates bus bar 30 from the external environment, preventing shorting. Outer dielectric 34 can be made of the same or a different dielectric material than inner dielectric 26. Outer dielectric 34 can be, for example, a polyimide, polyurethane, or silicone. If conductive tube 24A is a carbon-filled plastic, then outer dielectric 34 can be made of the same plastic that is unfilled or filled with glass fiber.
Protection layer 36 is an optional external layer of printed heater tube 20A that adds extra protection to PTC heater 28. Protection layer 36 can defend against handling and abrasion damage, and can add pressure strength to the assembly. Protection layer 36 can optionally be conductive for both static discharge and lightning protection. Protection layer 36 can be, for example, a braided metallic wire such as stainless steel or titanium, braided aramid, or braided dry fiberglass. If conductive tube 24A is a rigid tube, then protection layer 36 can alternatively be a carbon fiber or fiberglass composite made with epoxy, phenolic, or benzoxazine resin. Such a carbon fiber or fiberglass composite would be braided or spiral-wound for further strength. Protection layer 36 can alternatively be made of multiple sub-layers.
Specifically, non-conductive tube 24B differs from tube 24A of
The use of a non-conductive tube 24B in printed heater tube 20B eliminated the need for inner dielectric 26, as there is no electrical insulation needed between tube 24B and PTC heater 28 (or bus bar 30). For this reason, PTC heater 28 and bus bar 30 can be additively manufactured directly onto the surface of nonconductive tube 24B.
As shown in
In
In
Similarly, in
The disclosed printed heater tubes with PTC heaters are self-limiting heated components that are lightweight and compact on the surface of tubes transporting fluid.
The following are non-exclusive descriptions of possible embodiments of the present invention.
A heater tube assembly includes a tube, a bus bar network on the tube, a positive temperature coefficient heater on the tube, a closeout adhesive securing the bus bar network and the positive temperature coefficient heater to the tube, and an outer dielectric layer overlaying the bus bar network and the positive temperature coefficient heater. The bus bar network includes one or more layers of a first additively manufactured conductive ink. The positive temperature coefficient heater comprising one or more layers of a second additively manufactured conductive ink. The positive temperature coefficient heater is electrically connected to the bus bar network.
The assembly of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
The tube is a conductive material selected from the group consisting of stainless steel and titanium.
The assembly includes an inner dielectric layer separating the bus bar network and the positive temperature from the tube.
The tube is a non-conductive material selected from the group consisting of polyetherimide, polyetheretherketone, polyphenylene sulfide, polyimide, ethylene tetrafluoroethylene, polyvinylchloride, polyvinylidene difluoride, and combinations thereof.
The tube includes glass fibers, glass spheres, glass hollow spheres, carbon black, carbon nanotubes, or carbon fibers.
The assembly includes a liner comprising a material selected from the group consisting of fluoropolymers, fluoroelastomers, silicone, polyolefin, acrylonitrile butadiene rubbers, ethylene propylene diene monomer rubbers, polyurethane, and combinations thereof.
The bus bar network comprises at least one hot bus bar and at least one neutral bus bar.
The bus bar network comprises a geometric pattern selected from the group consisting of a spiraled pattern, a redundant dual-circuit pattern, a crisscross pattern, or combinations thereof.
The first additively manufactured conductive ink is a silver-filled ink.
The positive temperature coefficient heater comprises a sheet covering at least a portion of the tube.
The positive temperature coefficient heater comprises a single sheet spiraled around the tube.
The positive temperature coefficient heater comprises a plurality of bands around the tube in parallel.
The width of each of the plurality of bands increases from a first end of the tube to a second end of the tube.
The second additively manufactured conductive ink is a positive temperature coefficient ink.
The closeout adhesive is a pressure sensitive adhesive or ethylene-vinyl acetate.
The outer dielectric layer comprises a material selected from the group consisting of braided stainless steel wire, braided titanium wire, braided aramid, braided dry fiberglass, carbon fiber composites, fiberglass composites, and combinations thereof.
The assembly includes one or more protection layers overlaying the outer dielectric layer.
A heater tube assembly includes a tube, a bus bar network including at least one hot bus bar and at least one neutral bus bar on the tube, a heater on the tube having a thickness between 0.0001 and 0.010 inches, a closeout adhesive securing the bus bar network and the heater to the tube, and an outer dielectric layer overlaying the bus bar network and the heater. The bus bar network is made of one or more layers of a first additively manufactured conductive ink, and the bus bar network is a geometric pattern selected from the group consisting of a spiraled pattern, a redundant dual-circuit pattern, a crisscross pattern, or combinations thereof. The heater includes a plurality of layers of a second additively manufactured conductive ink, each of the plurality of layers has a thickness of between 1 and 100 microns, and the heater is electrically connected to the bus bar network.
A method of making a heater tube assembly includes additively manufacturing one or more layers of a first conductive ink on a tube to create a bus bar, additively manufacturing one or more layers of a second conductive ink on a tube to create a positive temperature coefficient heater overlapping with the bus bar, closing out the bus bar and the positive temperature coefficient heater with an adhesive, and encapsulating the bus bar and the positive temperature coefficient heater with an outer dielectric layer.
The method of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
Additively manufacturing is done with direct printing with extruded ink by micro-dispensing pumps, inkjet printing, or aerosol-gel printing.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by one skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.