The micro-manipulation of fluids has tremendous potential in a wide variety of industrially relevant technologies and has seen substantial interest and development over the past several years. For example, in fields such as electronic printing technology using inkjet printers, the ability to accurately, reliably and reproducibly deliver precise quantities of a fluid to a particular location on a receiving medium becomes ever more critical as image quality improves and hence dots per inch increases. In addition, as the number and complexity of fluids manipulated or ejected increases, the susceptibility of the microfluidic device to degradation by components in those fluids also may increase, leading to a reduction in reliability. Further, demand is increasing to reduce the weight and compactness of the fluid ejector head as well as to reduce the cost of the fluid ejector head by utilizing devices that are easier to both assemble and adapt to high volume manufacturing lines. Such demands place additional requirements on both the processes and the materials.
In current use are a wide variety of highly efficient inkjet printing systems capable of dispensing ink in a rapid and accurate manner. Commercial products such as computer printers, graphics plotters, facsimile machines, and multi-function devices have been implemented with inkjet technology. However, there is a demand by consumers for ever-increasing improvements in speed and image quality. In addition, consumers increasingly insist on longer lasting fluid ejection cartridges. Inkjet cartridges typically include a fluid reservoir that is fluidically coupled to a fluid ejector head. One way to increase the speed of printing is to increase number of nozzles or fluid ejection elements contained on the fluid ejector head thus, increasing the size of the fluid ejector head, thereby ejecting fluid over a larger swath of the receiving medium. Each nozzle in a fluid ejector head generally includes a fluid ejection element, and a fluid containing chamber surrounding or adjacent to that fluid ejection element. During operation, the chamber receives fluid from a fluid supply through an inlet channel. The activation of the fluid ejection element ejects the fluid as a droplet through the nozzle and onto the receiving medium. As the number of fluid ejection elements increases, the amount of circuitry necessary to generate more timing and control signals, at a given time, substantially increases. Generally, to keep the number of electrical connections to a manageable number, many of the fluid ejection elements are formed on silicon substrates. The utilization of silicon substrates enables the forming of the electronic circuitry and memory cells, necessary to generate the control, timing, and drive signals to activate the fluid ejection elements, on the same substrate on which the fluid ejection elements are formed. Although this provides for a decrease in the number of electrical interconnects, it also greatly increases the cost of each fluid ejection cartridge as the size increases since fewer die can be formed on each wafer. In addition, as the complexity of these devices increases, the yields decrease which increases the cost.
Another way to increase the speed of printing is to move the print or fluid ejection cartridge faster across the print medium. However, if the fluid ejection cartridge includes both the fluid reservoir and the energy converting elements utilized to eject the ink then longer lasting print cartridges typically would require larger ink reservoirs, with the corresponding increase in mass associated with the additional ink. This increase in mass requires more costly and complex mechanisms to move at even higher speeds to produce the increased printing speed. For color printers, typically, requiring a black ink cartridge and 3 color cartridges this increase in mass is further exacerbated by requiring four ink reservoirs.
The ability to develop higher performance fluid dispensing systems, that are cheaper smaller and more reliable, will enable the continued growth and advancements in inkjet printing and other micro-fluidic devices. In addition, the ability to optimize fluid ejection systems will open up a wide variety of applications that are currently either impractical or not cost effective.
a is a schematic view of a fluid dispensing system according to an embodiment of the present invention;
b is a schematic view of a fluid dispensing system according to an alternate embodiment of the present invention;
c is a schematic view of a portion of a fluid ejector array according to an embodiment of the present invention;
a is an isometric view of a fluid dispensing system according to an embodiment of the present invention;
b is a schematic representation of some of the functional elements included in the fluid dispensing system shown in
a is a cross-sectional view of a fluid ejection array element according to an embodiment of the present invention;
b is a cross-sectional view of a photodetector according to an embodiment of the present invention;
a is an isometric view of a fluid dispensing system according to an alternate embodiment of the present invention;
b is a cross-sectional view along 5b-5b showing a portion of the fluid ejector array and photon source shown in
c is a cross-sectional view along 5c-5c showing the fluid ejector array shown in
a is a simplified cross-sectional view of an individual element of an electroluminescent array according to an embodiment of the present invention;
b is an isometric cross-sectional view of an individual carbon nanotube photon emitter of a photon source according to an embodiment of the present invention;
An embodiment of fluid dispensing system 100 of the present invention is shown in
A drop-firing controller (not shown) provides signals to photon source 140 to selectively activate photon source 140 when photonically aligned with a desired photodetector 130 of fluid ejector array 102. Photons 110 emitted from photon source 140 are absorbed by photodetector 130; and generate an activation signal activating fluid ejector 120 to eject fluid from fluid dispensing system 100. Thus, photons emitted from photon source 140 selectively interact with the plurality of photodetectors generating activation signals that selectively activate the plurality of fluid ejectors ejecting fluid away from the fluid ejector array. The light output of photon source 140 also may be modulated so that information is contained in the photon beam impinging on photodetector 130. This information is utilized, either directly or indirectly through further signal processing, to actuate fluid ejector 120.
Photon source 140, may be any modulatable photon source of sufficient intensity to generate a signal in a photodetector. In this embodiment, photon source 140 includes any photon source emitting photons in some portion of the electromagnetic spectrum from the ultraviolet region to the infrared region including visible radiation. For example, photon source 140 may be a light emitting diode (LED), a laser (in particular a solid state laser), a lamp, a luminescent source (such as an electroluminescent source utilizing either an ac or dc electric field), to name a few sources. In addition, the photon source may also utilize what is generally referred to as a photonic crystal providing, for example, increased efficiency.
Fluid ejector 120 may be any device capable of imparting sufficient energy to the fluid to cause ejection of fluid from a chamber. For example, compressed air actuators, such as utilized in an airbrush, or electro-mechanical actuators or thermal mechanical actuators may be utilized to eject the fluid from the chamber. In alternative embodiments, fluid ejector 120 also may include an energy converting element such as a resistor or a piezoelectric transducer.
Photodetector 130 may be any device capable of interacting with photons sufficient to generate a signal distinguishable over the noise and leakage current of the device. For example, photoconductive devices such as a photodiode or phototransistor, or photovoltaic devices such as p-n silicon or selenium cells, or photoemissive devices may all be utilized. The particular photodetector utilized will depend on various parameters such as the wavelength region emitted by the particular photon source utilized, the amount of amplification of the detection signal, and the particular fluid ejection characteristics of the fluid ejector utilized, to name just a few. For example, in one embodiment photodetector 130 may be a photodiode, photon source 140 may be an LED and fluid ejector 120 may include an energy converting element such as a thermal resistor. When a pulse of photons is emitted from the LED, the electrical conductivity of the photodiode is increased to provide a drive current from a power supply to heat the thermal resistor. The energy impulse applied across the thermal resistor rapidly heats a component in the fluid above its boiling point causing vaporization of the fluid component resulting in an expanding bubble that ejects a fluid drop from a chamber (not shown). In alternate embodiments, other fluid energy converting elements such as piezoelectric, acoustic, mechanical, and electrostatic generators may also be utilized. For example, a piezoelectric element utilizes a voltage pulse to generate a compressive force on the fluid resulting in ejection of a drop of the fluid
It should be noted that the drawings are not true to scale. Further, various elements have not been drawn to scale. Certain dimensions have been exaggerated in relation to other dimensions in order to provide a clearer illustration and understanding of the present invention.
In addition, although some of the embodiments illustrated herein are shown in two dimensional views with various regions having depth and width, it should be clearly understood that these regions are illustrations of only a portion of a device that is actually a three dimensional structure. Accordingly, these regions will have three dimensions, including length, width, and depth, when fabricated on an actual device. Moreover, while the present invention is illustrated by various embodiments, it is not intended that these illustrations be a limitation on the scope or applicability of the present invention. Further it is not intended that the embodiments of the present invention be limited to the physical structures illustrated. These structures are included to demonstrate the utility and application of the present invention to presently preferred embodiments.
A simplified schematic diagram of an alternate embodiment of fluid dispensing system 100 is shown in
An alternate embodiment of the present invention where each optical triggering circuit 134 includes voltage level shifter 136, memory device 138 such as a latch, and photodetector 130 as shown in
In one embodiment, transistors 150 and 151 are metal-oxide-semiconductor field effect transistors (MOSFETs), as shown in
Still referring to
An exemplary fluid dispensing system, printer 201, that may employ the present invention is shown in outline form in the isometric drawing of
Some of the functional elements included in fluid dispensing system 200, according to an embodiment of the present invention, are shown in a block diagram in
By selectively activating photon source 240 fluid drops are ejected from selective fluid ejectors to form predetermined fluid dispensed patterns, forming images, alphanumeric characters or combinations thereof using dot matrix manipulation. In alternate embodiments, the fluid dispensed patterns will be determined by the particular application in which fluid dispensing system 200 is utilized, such as creating a dosage form on an ingestible sheet, creating an adhesive pattern on an adherend, or selectively depositing a material on a substrate to create an electronic device. Generally, a user's computer (not shown) determines the dot matrix manipulation and instructions are transmitted to a microprocessor-based, electronic controller within the fluid dispensing system 200.
Other techniques employ a rasterization of the data in a host or user's computer such as a personal computer or PC (not shown) prior to the rasterized data being sent, along with the system control commands, to the system. This operation is under control of system driver software resident in the system's computer. The system interprets the commands and rasterized data to determine which fluid ejectors to fire. Still other system configurations or system architectures for the rasterization of data are possible. An arrow in
As can be appreciated from the exemplary embodiment shown in
An exemplary embodiment of fluid ejection array element 303 of fluid ejector array 302 of the present invention, is shown, in a cross-sectional view, in
Chamber layer 326 is selectively disposed over fluid ejector substrate surface 361 of substrate 360. In this embodiment, the fluid inlet channels (not shown) and the fluid distribution manifold (not shown) are formed in chamber layer 326 in and out of the plane of cross-sectional
Nozzle layer 325 may be formed of metal, polymer, glass, or other suitable material such as ceramic. In one embodiment chamber layer 326 and nozzle layer 325 are formed as a single layer. Such an integrated chamber and nozzle layer structure is commonly referred to as a chamber orifice or chamber nozzle layer. In a second embodiment, nozzle layer 325 is a polyimide film. Examples of commercially available nozzle layer materials include a polyimide film available from E.I. DuPont de Nemours & Co. sold under the trade name “Kapton”, a polyimide material available from Ube Industries, LTD (of Japan) sold under the trade name “Upilex.” In an alternate embodiment, nozzle layer 325 may be formed from a metal such as a nickel base enclosed by a thin gold, palladium, tantalum, or rhodium layer. In other alternative embodiments, nozzle layer 325 may be formed from polymers such as polyesters, polyethylene naphthalates (PEN), epoxies, or polycarbonates.
Fluid ejector 320 includes energy converting element 322, in this embodiment, shown in
The drop volume of fluid drop 304 may be optimized by adjusting various parameters such as nozzle bore diameter, nozzle layer thickness, chamber dimensions, chamber layer thickness, energy converting element dimensions, and the fluid surface tension to name a few. Thus, the drop volume can be optimized for the particular fluid being ejected as well as the particular application in which fluid ejector array 302 will be utilized. Fluid ejection array element 303 described in this embodiment can reproducibly and reliably eject drops in the range of from about 5 femto-liters to about 750 pico-liters depending on the parameters and structures of the fluid ejector array as described above. In this embodiment, the term fluid may include any fluid material such as inks, adhesives, lubricants, chemical or biological reagents, as well as fluids containing dissolved or dispersed solids in one or more solvents.
Photodetector 330 includes electrical interconnects 337 and photosensing layer 332 formed on fluid ejector substrate surface 361 of substrate 360. While photodetector 330 is represented as only a single layer in
A planar structure that may be utilized to form photodetector 330 is shown in a cross-sectional view in
An alternate embodiment of fluid ejection array element 403 of fluid ejector array 402 of the present invention is shown. In this embodiment, fluid ejector 420 and photodetector 430 are disposed on opposite sides of substrate 460. Substrate 460 has two opposing major surfaces substantially parallel to each other, first major surface 461 and second major surface 462. Fluid ejector 420 including fluid energy converting element 422 is disposed over first major surface 461 of substrate 460. Photodetector 430 is disposed over second major surface 462 with electrical through connect 470 electrically coupling photodetector 430 with fluid ejector 420 via an electrical trace (not shown) that is disposed on substrate 460 either in or out of the plane of the drawing. In this embodiment, substrate 460 is a mono-crystalline silicon substrate having a thickness of about 300-800 micrometers. However, in alternate embodiments, various glasses; ceramics such as aluminum oxide, boron nitride, silicon carbide, and sapphire; semiconductors such as gallium arsenide, indium phosphide, and germanium; and various polymers such as polyimides, and polycarbonates are just a few examples of the materials that may be utilized. Accordingly, the present invention is not intended to be limited to those devices fabricated in silicon semiconductor materials, but will include those devices fabricated in one or more of the available semiconductor materials and technologies known in the art, such as thin-film-transistor (TFT) technology using polysilicon on glass substrates. Further, substrate 460 is not restricted to typical wafer sizes, and may include processing a polymer sheet or film or glass sheet or for example a single crystal sheet or a substrate handled in a different form and size than that of conventional wafers or substrates. The actual substrate material utilized will depend on various system components such as the particular fluid ejector utilized, the particular fluid being ejected, the size and number of fluid ejectors utilized in the particular fluid ejector array, and the environment to which the fluid dispensing system will be subjected.
In this embodiment, fluid ejector 420 includes energy converting element 422, which is a thermal resistor. In alternate embodiments, other fluid energy converting elements such as piezoelectric, acoustic, and electrostatic generators may also be utilized. In still other embodiments, fluid ejector 420 may be any device capable of imparting sufficient energy to the fluid to cause ejection of fluid from a chamber, such as compressed air actuators, electromechanical actuators or thermal mechanical actuators. Chamber layer 426 is selectively disposed over first major surface 461 of substrate 460. Sidewalls 428 define or form fluid ejection chamber 427, around energy converting element 422, so that fluid, from fluid distribution channel 466 via fluid inlet channels 465, may accumulate in fluid ejection chamber 427. Activation of energy converting element 422 expels fluid from chamber 427. In alternate embodiments, depending on the particular material utilized for chamber layer 426, an adhesive layer (not shown) may also be utilized to adhere chamber layer 426 to substrate 460. Chamber layer 426, typically, is a photoimagible film that utilizes photolithography equipment to form chamber layer 426 on substrate 422 and then define and develop fluid ejection chamber 427.
Photodetector 430 includes electrical interconnects 437 and photosensing layer 432 formed on second major surface 462. Planarizing layer 439 is formed over photosensing layer 432 and electrical interconnects to provide electrical isolation and environmental protection of photosensing layer 432. In addition, planarizing layer 439 is sufficiently optically transparent in the wavelength region over which the photon source emits to provide a signal to noise ratio of at least two to one.
Photodetector 430 is represented as only a single layer in
An alternate embodiment of fluid dispensing system 500, of the present invention, includes fluid ejector array 502 having multiple rows of fluid ejectors and photodetectors, and photon source 540 having multiple rows and columns of photon sources is illustrated in
Fluid ejector array 502 includes a plurality of array elements 503 as shown in
Substrate 560, in this embodiment is substantially optically transparent with photodetector 530 disposed on the fluid ejector surface of substrate 560. However, in alternate embodiments photodetector 530 may be disposed on the backside or the non fluid ejector surface of substrate 560, wherein non-optically transparent substrates may also be utilized. An example of such a structure is shown in
As described above as carriage 511 is scanned across or over fluid ejector array 502 the various control circuitry described above selectively activates a photon emitter in photon source 540. The activation of the photon emitter in turn generates an actuation signal in the photodetector photonically coupled to the photon emitter at that particular time resulting in actuation of the fluid ejector 520 which in turn ejects fluid from nozzle 529 of that particular array element. For those embodiments utilizing a voltage level shifter or control circuitry, such as that shown in
Photon source array 547, as noted above, includes a 3×4 array of photon emitters 541. In this embodiment, photon emitters 541 may be any photon source generating sufficient intensity to generate a signal in photodetector 530. For example, photon emitters 541 may be a light emitting diode (LED), a solid state laser, a lamp, or an electroluminescent source. In addition, each photon emitter also has lens 544 and lens mount 545, mounted essentially over each photon emitter 541. The lens and lens mount assembly, in this embodiment, is attached or mounted to photon emitter array 547 utilizing precut epoxy adhesive strip 576. In alternate embodiments, the assembly may be attached to the photon emitter array utilizing any of the known attachment methods such as fasteners, mechanical clamping arrangements, alignment structures, dispensed adhesives, and combinations of these as just a few examples.
Lens 544 may be any glass or plastic lens providing the desired focusing properties for the particular photon source and photodetector utilized. In alternate embodiments, other focusing elements may also be utilized, such as a rod lens with a graded refractive index profile providing a refractive index which decreases in a predetermined manner (e.g. quadratically) with the distance from the lens axis. Nippon Sheet Glass Co. sells an example of such a rod lens under the tradename of SELFOC including SELFOC microlens or SELFOC fiber array.
Each lens 544 may be separately mounted to photon source array 547 utilizing separate lens mounts 545 or as illustrated in
As noted above photon source 540 in this embodiment includes a 3×4 array of photon emitters and fluid ejector array 502 includes 4 rows of fluid ejectors. For example, in one embodiment, printing at 300 dots per inch both black and color ink on an 8.5 inch by 11 inch paper sheet, one may utilize a fluid ejector array having 4 rows of fluid ejectors one row for black and 3 rows, one each, for cyan, magenta, and yellow inks. If we assume that we will print only over 8 inches of the 8.5 inch width we find that each row will contain 2400 fluid ejectors providing an array of 2400×4 fluid ejectors. In alternate embodiments, fluid ejector array 502 may include an m×n array of fluid ejectors 520 electrically coupled to an m×n array of photodetector elements 530, and photon source 540 includes a j×k array of photon emitters 541, where j is less than or equal to m, and k is less than or equal to n. For those embodiments where k is less than n either carriage 511 also includes a motion mechanism to step the photon source in the ±Y direction or fluid ejector array 502 includes such a motion mechanism. In still other embodiments j is less than m and m is an integral multiple of j, and k is less than n and n is an integral multiple of k.
An example of an alternative structure that may be utilized for a photon focusing array is shown in an isometric view in
An individual element of photon source array 547 (see
Electroluminescent layer 726 may be formed utilizing any of the wide variety of inorganic phosphors, organic materials including polymeric materials, and hybrid layers containing inorganic/organic dispersions. Examples of inorganic phosphors that may be utilized include zinc sulfide, zinc selenide, zinc telluride, manganese sulfide, cadmium telluride, cadmium sulfide, cadmium selenide. Examples of organic materials that may be utilized include aluminum quinolate, 10-azoanthracene (i.e. acridine), 3,6 acridinediamine, carbazole and substituted carbazoles;
Referring to
Referring to
A flow diagram of a method of manufacturing a fluid dispensing system, according to an embodiment of the present invention, is shown in
The present invention is not intended to be limited to those devices fabricated in silicon semiconductor materials, but will include those devices fabricated in one or more of the available semiconductor materials and technologies known in the art, such as thin-film-transistor (TFT) technology using polysilicon on glass substrates. Further, the substrate is not restricted to typical wafer sizes, and may include processing a polymer sheet or film or glass sheet or for example a single crystal sheet or a substrate handled in a different form and size than that of conventional wafers or substrates. The actual substrate material utilized will depend on various system components such as the particular fluid ejector utilized, the particular fluid being ejected, the size and number of fluid ejectors utilized in the particular fluid dispensing system, and the environment to which the fluid dispensing system will be subjected.
In those embodiments utilizing a fluid ejector that includes a fluid energy converting element, the energy converting element is generally formed on the substrate utilizing conventional semiconductor processing equipment involving various lithography and etching processes. In alternative embodiments, micromolding, electrodeposition, electroless deposition may also be utilized. For example, in those embodiments utilizing thermal resistor elements, a resistor is formed as a tantalum aluminum alloy utilizing conventional semiconductor processing equipment, such as sputter deposition systems for forming the resistor and etching and photolithography systems for defining the location and shape of the resistor layer. In alternate embodiments, resistor alloys such as tungsten silicon nitride, or polysilicon may also be utilized. In other alternative embodiments, fluid drop generators other than thermal resistors, such as piezoelectric transducers, or ultrasonic transducers may also be utilized. For example, in those embodiments utilizing a piezoelectric element a flexible membrane or wall is formed on the substrate and a piezoceramic element, is formed or attached to the non-fluid side of the membrane. In still other embodiments, such as those utilizing compressed air the fluid ejector may be created with a valve in fluid communication with a fluid chamber.
Photodetector forming process 920 utilizes conventional thin film processing equipment to form a photodetector. The photodetector may be formed on the substrate utilized to form the fluid ejector or fluid energy converting element. For example, the photodetector may be a photodiode formed by creating doped wells in the substrate of opposite polarity to the dopant of the substrate (e.g. p-type wafer with n-type wells or n-type wafer with p-type wells) if a semiconductor substrate is utilized. Electrical interconnects are formed to connect with both the substrate and the doped well. Another example, is the deposition of polysilicon or epitaxial silicon on a buried oxide with corresponding doped well regions formed in the deposited layer to generate a photodiode. By utilizing various combinations of doped wells and layers, various photodiodes such as p-i-n photodiodes or photodiodes optimized to operate in the avalanche region as well as phototransistors are just a few examples of structures that may be utilized to form the photodetector. The particular photodetector utilized will depend on various parameters such as the wavelength and intensity of the photon source utilized, presence or absence of amplifying devices, firing speed of the fluid ejector, as well as the particular environment in which the fluid dispensing system will be utilized.
Coupling process 930 is utilized to electrically couple the photodetector to the fluid ejector or fluid energy converting element depending on the particular embodiment being utilized. For example, for those embodiments utilizing a substrate that is sufficiently optically transparent to the wavelength region emitted from the photon source the photodetector may be formed on the same major surface of the substrate as the fluid ejector. In such embodiments conventional semiconducting equipment is generally utilized to form electrical conductors coupling the photodetector to the fluid ejector. The electrical conductors, may be formed from any of the metals such as aluminum including aluminum-copper-silicon alloys, tungsten, copper, gold, palladium, or heavily doped polysilicon. For those embodiments where the substrate does not have sufficient transmittance in the wavelength region emitted from the photon source to provide a useable signal to noise ratio, the photodetector may be formed on the opposing major surface to that utilized to form the fluid ejector. In this case through holes or through vias may be formed in the substrate utilizing dry or wet etching techniques or combinations of both. For example to form the through vias in a silicon substrate a dry etch may be used when vertical or orthogonal sidewalls are desired. However, when sloping sidewalls are desired a wet etch such as tetra methyl ammonium hydroxide (TMAH) may be utilized. In addition, combinations of wet and dry etch may also be utilized when more complex structures are utilized to form the vias. Other processes such as laser ablation, reactive ion etching, ion milling including focused ion beam patterning, may also be utilized to form the through holes depending on the particular substrate material utilized. Micromolding, electroforming, punching, or chemical milling are also examples of techniques that may be utilized depending on the particular substrate material utilized. Sputter deposition, thermal evaporation, electrodeposition, electroless deposition are a few examples of processes that may be utilized to fill the through hole with an electrical conductor. Electrical traces from the through hole or via to the photodetector and fluid ejector may then be formed utilizing processes described above. In addition, for those embodiments utilizing an amplifier or control circuitry, such as that shown in
Depending on the particular embodiment utilized as well as the particular application in which the fluid dispensing system may be utilized, the following processes may, also, be used. A chamber layer forming process may be utilized to form the fluid chamber around the fluid ejector. The particular process depends on the particular material chosen to form the chamber layer, or the chamber orifice layer when an integrated chamber layer and nozzle layer is used. The particular material chosen will depend on parameters such as the fluid being ejected, the expected lifetime of the fluid dispensing system, the dimensions of the fluid ejection chamber and fluidic feed channels among others. Generally, conventional photoresist and photolithography processing equipment or conventional circuit board processing equipment is utilized. For example, the processes used to form a photoimagible polyimide chamber layer would be spin coating and soft baking. However, forming a chamber layer, from what is generally referred to as a solder mask, would typically utilize either a coating process or a lamination process to adhere the material to the substrate. Other materials such as silicon oxide or silicon nitride may also be formed into a chamber layer, using deposition tools such as plasma enhanced chemical vapor deposition or sputtering.
A side wall definition process may be utilized to form the sidewalls and define the geometrical structure of the fluid ejection chamber. The side wall definition process typically utilizes photolithography tools for patterning. For example, after either a photoimagible polyimide or solder mask has been formed on the substrate, the chamber layer would be exposed through a mask having the desired chamber features. The chamber layer is then taken through a develop process and typically a subsequent final bake process after develop. Other embodiments may also utilize a technique similar to what is commonly referred to as a lost wax process. In this process, typically a lost wax or sacrificial material that can be removed, through, for example, solubility, etching, heat, photochemical reaction, or other appropriate means, is used to form the fluidic chamber and fluidic channel structures as well as the orifice or bore. Typically, a polymeric material is coated over these structures formed by the lost wax material. The lost wax material is removed by one or a combination of the above-mentioned processes leaving a fluidic chamber, fluidic channel and orifice formed in the coated material.
A nozzle or orifice forming process is utilized to form a nozzle layer and form the nozzles or bores in the nozzle layer. The nozzle forming process depends on the particular material chosen to form the nozzle layer. The particular material chosen will depend on parameters such as the fluid being ejected, the expected lifetime of the fluid dispensing system, the dimensions of the bore, bore shape and bore wall structure among others. Generally, laser ablation may be utilized; however, other techniques such as punching, chemical milling, or micromolding may also be used. The method used to attach the nozzle layer to the chamber layer also depends on the particular materials chosen for the nozzle layer and chamber layer. Generally, the nozzle layer is attached or affixed to the chamber layer using either an adhesive layer sandwiched between the chamber layer and nozzle layer, or by laminating the nozzle layer to the chamber layer with or without an adhesive layer.
As described above, some embodiments may utilize an integrated chamber and nozzle layer structure referred to as a chamber orifice or chamber nozzle layer. This layer will generally use some combination of the processes already described depending on the particular material chosen for the integrated layer. For example, in one embodiment a film typically used for the nozzle layer may have both the nozzles and fluid ejection chamber formed within the layer by such techniques as laser ablation or chemical milling. Such a layer can then be secured to the substrate using an adhesive. In an alternate embodiment a photoimagible epoxy can be disposed on the substrate and, then using conventional photolithographic techniques, the chamber layer and nozzles may be formed, for example, by multiple exposures before the developing cycle. In still another embodiment, as described above, the lost wax process may also be utilized to form an integrated chamber layer and nozzle layer structure.
A fluid inlet channel forming process may be utilized to form fluid inlet channels and fluid distribution channels in the substrate. The fluid inlet channel forming process depends on the particular material utilized for the substrate. For example, to form the fluid inlet channels in a silicon substrate, a dry etch may be used when vertical or orthogonal sidewalls are desired. However, when sloping sidewalls are desired a wet etch such as tetra methyl ammonium hydroxide (TMAH) may be utilized. In addition, combinations of wet and dry etch may also be utilized when more complex structures are utilized to form the fluid inlet channels. Other processes such as laser ablation, reactive ion etching, ion milling including focused ion beam patterning, may also be utilized to form the fluid inlet channels depending on the particular substrate material utilized. Micromolding, electroforming, punching, or chemical milling are also examples of techniques that may be utilized depending on the particular substrate material utilized.
Referring to
Selective photon activation process 1020 is utilized to selectively activate a photon emitter, of the photon source array, to emit photons. Under control of the drop firing controller and the position controller, the photon source disposed on the carriage scans across or over at least a portion of the fluid ejector array selectively emitting photons from a particular photon emitter when that emitter is photonically coupled to a desired photodetector. Photon activation process 1020 generally depends on the particular photo-site being activated; however, generally both amplitude modulation and pulse width modulation may be utilized to control the intensity of photons emitted and time over which photons are emitted. Depending on the particular system utilized (i.e. photon source, photodetector, and the fluid ejector), the photon activation process may utilize various pulse schemes from simple square wave pulses to more complex wave patterns, depending on, for example, the particular pressure response function of the fluid ejector.
Photo-generating activation signal process 1030 is utilized to generate a signal to actuate the fluid ejector. Photons emitted from the photon source and absorbed by the photodetector are converted into an electrical signal thereby generating an activation signal. For those embodiments utilizing a photodiode, the photons absorbed in the active region of the photodiode increase the electrical conductivity of the photodiode generating the activation signal. For those embodiments utilizing a phototransistor coupled to control circuitry, photons absorbed in the base region of the phototransistor increase the electrical conductivity and generate a current that may be coupled to a memory device as shown in
Fluid ejector activating process 1040 is utilized to activate the fluid ejector. The fluid ejector disposed on or within the fluid ejector array and electrically coupled to the activated photodetector provides an energy impulse to the fluid selectively ejecting fluid drops from that particular fluid onto the fluid receiving medium. Fluid ejector activating process depends on the particular fluid ejector utilized. For example, those embodiments utilizing a photodiode coupled to a thermal resistor the increase in electrical conductivity of the photodiode provides a drive current from a power supply causing an energy impulse to be distributed throughout the thermal resistor rapidly heating a component in the fluid above its boiling point to cause vaporization of the fluid component resulting in an expanding bubble that ejects fluid from the fluid ejector. Another example is those embodiments utilizing a piezoelectric transducer, the photo-generated activation signal applies a voltage pulse across the piezoelectric element to generate a compressive force on the fluid, resulting in ejection of a drop of the fluid.
This application is a divisional of U.S. patent application Ser. No. 10/631,329 filed Jul. 30, 2003.
Number | Date | Country | |
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Parent | 10631329 | Jul 2003 | US |
Child | 11228899 | Sep 2005 | US |