Fluid Tilt Sensor Within Ink Tank Supply Item for Micro-Fluid Applications
A container for holding a volume of fluid and having a housing defining an interior for retaining the volume of fluid; at least one in-tank tilt sensor connected to a controller and disposed inside the housing for generating a signal corresponding to a level of fluid inside the housing; and a support material attached to the housing and connected to the at least one in-tank tilt sensor to mechanically support the at least one in-tank tilt sensor such that the at least one in-lank tilt sensor is not in direct contact with the fluid inside the housing. The in-tank tilt sensor detects a change in fluid level which may only be caused by tilting of the imaging device. When tilting is registered, protective action is taken to prevent fluid from leaking.
This matter claims priority as a divisional patent application of U.S. Ser. No. 13/241,980, filed Sep. 23, 2011, having the same title.
FIELD OF THE DISCLOSUREThe present disclosure relates generally to micro-fluid applications, such as inkjet printing. The present disclosure relates particularly to a fluid container that senses tilting during such application. Tilting is determined based on capacitive sensing by in-tank tilt sensors.
BACKGROUNDThe art of printing images with micro-fluid technology is relatively well-known. A permanent or semi-permanent printhead has access to a local or remote supply of fluid. The fluid is usually stored in a container, such as a tank or a cartridge. In an imaging device having a local supply of fluid, the container is installed within the housing of the imaging device. The fluid ejects from the printhead nozzles to a print media in a pattern of pixels corresponding to images being printed.
During printing, the printhead maintains a backpressure so that fluid cannot leak out of the printhead nozzles. Hence, tilting an imaging device having a local supply of fluid may cause serious issues. This is most commonly a problem for imaging devices which rely on the difference in the height of the printhead and the fluid container for setting the backpressure of the printhead.
Knowing whether or not an imaging device is tilted lends itself to a variety of consumer features. Imaging devices can warn users that the imaging device is tilted. Also, an operation of me imaging device may be suspended if the imaging device is lilted in order to avoid fluid spillage. Users may also be advised to perform corrective measures.
Manufacturers have implemented a variety of container tilt measurement systems and techniques. Each has its own set of advantages and problems. Some are cheap while others are costly. Some work as intended while others have proven so poorly that users regularly ignore them. Still others are complex, including complicated processing, algorithms. The optimum balance is to provide accurate tilt measurement over a lifetime of a fluid container, but without adding complexity or cost.
One existing method for detecting tilting is to install a traditional electrical tilt sensor on the imaging device's circuit board. When this sensor detects that the imaging device is tilted, the firmware closes a fluidic valve between the printhead and the fluid container in order to prevent the fluid from leaking out of the printhead nozzles. A dedicated electrical tilt sensor increases the cost of the imaging device.
Accordingly, a need exists in the art for an alternative method for detecting tilt in the imaging device.
SUMMARYThe above-mentioned and other problems become solved with capacitive tilt detection system utilizing existing sensors that an imaging device uses in detecting the level of fluid in a fluid container.
The basic concept of capacitive tilt detection is a method by which a pair of metal plates or electrodes are placed on the fluid container to constitute a capacitive in-tank sensor with one electrode being used in conjunction with a transmit circuit, and the other being used as a receiver, in imaging devices which use capacitive in-tank sensors to measure the level of fluid inside the container, the same sensors may be utilized to determine tilting of the container. Utilizing the same sensors to determine the level of fluid and to determine tilting of the container lowers the manufacturing cost.
Upon application of electrical energy, circuitry measures capacitance of the fluid residing in the space between the capacitive electrodes. When the transmit electrode is stimulated, the receiver electrode and circuitry measures the capacitance of the fluid residing in the space between the capacitive electrodes. The capacitance varies according to the volume of fluid residing in the space between the capacitive electrodes. The volume of fluid between the capacitive electrodes changes as the level of fluid between the capacitive electrodes changes. This method of using capacitive electrodes in detecting tilting of the container has several benefits inherent to it, including that no probe or other sensor intrusion into the tank is needed to measure capacitance, no clear window is needed for optical sensing at each level and the same pair of capacitive electrodes used in ink level detection provides the capacitance readings to be used in detecting tilting during the lifetime of the fluid container.
The present disclosure uses the concept and process by which capacitive electrodes are used to detect titling of a fluid container or ink tank, and to take the appropriate precautions to prevent the imaging device from possibly leaking fluid, such as by closing a valve to prevent fluid from flowing to the printhead. The present disclosure operates to detect tilt by measuring changes in fluid level which are caused by lilting of the fluid container.
In a representative embodiment, a container for an imaging device holds a volume of fluid. Its housing defines an interior and a fluid exit port (not shown). A pair of metal plates or electrodes is disposed on the housing. These metal plates function as capacitive electrodes and measure the capacitance of the volume of fluid between the capacitive electrodes. The capacitance reading is in proportion to the volume of fluid between the capacitive electrodes but not necessarily to the entire volume of fluid inside the container. Even with a constant volume of fluid, the capacitance readings provided by the capacitive electrodes may vary if the container is tilted towards various directions at varying extent. Changes in the volume of fluid between the capacitive electrodes equate to changes in the capacitance readings. When the container is not tilted, the capacitance reading provided by the capacitive electrodes may be used as a reference capacitance during tilt detection. For example, when the same container with the same volume of fluid is tilted towards the location of the capacitive electrodes, the volume of fluid between the capacitive electrodes increases and the capacitance reading also increases. Conversely, when the container is tilted towards the opposite direction, the volume of fluid between the capacitive electrodes decreases and the capacitance reading also decreases. In each occasion, tilting may be detected by comparing the capacitance reading to the reference capacitance or the capacitance reading when the container is not tilted. The differences between the capacitance readings may be used to determine the extent of the tilt.
Further embodiments contemplate setting a new reference capacitance after a predetermined period of operation of the imaging device, taking into account the amount of fluid consumed or used during operation. The latest capacitance reading which, is within allowable variances may also be saved into a memory to serve as the next reference capacitance.
Still other embodiments contemplate first and second electrode pairs on opposing sides of a housing. When one pair gives capacitance readings higher or lower than its initial or earlier readings and the other pair gives contrarian capacitance readings lower or higher than its initial or earlier readings, respectively, tilt of the housing is made known. The extent of tilting may be also inferred based on amounts of change from one reading to the next.
These and other embodiments are set forth in the description below. Their advantages and features will become readily apparent to skilled artisans. The claims set forth particular limitations.
The accompanying drawings incorporated in and forming a part of the specification, illustrate several aspects of the present disclosure, and together with the description serve to explain the principles of the present disclosure, in the drawings:
In the following detailed description, reference is made to the accompanying drawings where like numerals represent like details. The embodiments are described in sufficient detail to enable those skilled in the art to practice the present disclosure. It is to be understood that other embodiments may be utilized and that process, electrical, and mechanical changes, etc., may be made without departing from the scope of the present disclosure. The following detailed description, therefore, is not to be taken in a limiting sense and the scope of the present disclosure is defined only by the appended claims and their equivalents.
With reference to
In
The support material 25 may hold the at least one pair of capacitive electrodes 10a and may provide the surfaces of the capacitive electrodes 10a wish a cover such that there is no direct contact between the capacitive electrodes 10a and the fluid. In this example embodiment, the possibility of any chemical reaction between the capacitive electrodes 10a and the fluid is small thus, the chemical composition of the fluid may be preserved and the integrity of the capacitive electrodes 10a may not be affected. Support material 25. including the capacitive electrodes 10a, may be also configured as a modular nosepiece that attaches to containers of various sizes. In this way, commonality in manufacturing may exist with in-tank sensors regardless of the size of the container to which they attach.
If the variance between the first capacitance reading F1 and the reference capacitance Fref is within the allowable positive variance X, the variance may be compared to the allowable negative variance Y (108). If the variance is outside the allowable negative variance Y, the performance of the printing job may be suspended for one second (110) and similar procedure may be performed as when the variance is outside the allowable positive variance X. If, on the other hand, the variance is within the allowable negative variance Y, no tilt is detected, the first capacitance reading F1 may be saved into the memory for use in determining the next reference capacitance Fnref (124) and operation may be continued (126).
In determining the new reference capacitance Fnref, the previous capacitance reading F1 or F2, as the case may be, which is within allowable variances X, Y, may be made as the new reference capacitance Fnref in the next cycle of operation. The new reference capacitance Fnref may also be based on the previous capacitance reading F1 or F2, as the case may be, which is within allowable variances X, Y, and the amount of fluid consumed during a printing operation.
When tilt is detected and corrective measure is performed, the previously-closed pinch valves may be opened (122). When the printing job is finished, the imaging device may be turned off (130) by the user and the appropriate pinch valves may be closed (142) to prevent fluid from leaking when the imaging device is tilted unintentionally during a state of non-use, such as when the imaging device is moved or transported. On the other hand, when the printing job is finished, but the imaging device is not turned off (130), availability of a new print job may be determined (132). If a new print job is available, the same procedure for determining tilting while performing a print job may be repeated. However, if no new print job is available (132), and the imaging device is kept on (130), tilting may be determined (134), If a tilt is detected (136), appropriate pinch valves may be closed (138) to avoid leaking of fluid in the printhead. A user may turn off the imaging device at this stage (140) to end an operation.
When a tilt is detected (136), with the appropriate pinch valves closed (138), and the imaging device not turned off (140), availability of a new print job may be determined (132). If a new print job is available (132), the entire procedure for detecting a tilt may be repeated (126). If no new print job is available (132), tilting may be monitored continuously (134).
In still another embodiment,
The foregoing illustrates various aspects of the present disclosure. It is not intended to be exhaustive. Rather, it is chosen to provide the best illustration of the principles of the present, disclosure and its practical application to enable one of ordinary skill in the art to utilize the present disclosure, including its various modifications that naturally follow. All modifications and variations are contemplated within the scope of the present disclosure as determined by the appended claims. Relatively apparent modifications include combining one or more features of various embodiments with features of other embodiments.
Claims
1. A method of detecting tilting of a container for holding a volume of fluid, the container for consumable use of the fluid in an imaging device and having a housing, defining an interior to retain the volume of fluid and at least one pair of opposed electrodes disposed in the interior having a capacitance that varies in response to an amount of fluid existing between the opposed electrodes, a higher said capacitance corresponding to a higher said amount of fluid existing between the opposed electrodes, comprising:
- obtaining a first capacitance measurement value from the pair of opposed electrodes;
- obtaining a second capacitance measurement: value from the pair of opposed electrodes; and
- ascertaining tilt of the housing by determining whether the second capacitance measurement value is higher than the first capacitance measurement value.
2. The method of claim 1, further including determining whether the second capacitance measurement value remains higher than the first capacitance measurement value for a predetermined amount of time.
3. The method of claim 2, further including pinching closed a valve in the imaging device to stop fluid flow if the second capacitance measurement value remains said higher than the first capacitance measurement value for at least one second.
Type: Application
Filed: Jun 27, 2013
Publication Date: Nov 14, 2013
Inventors: Robert H. Muyskens (Lexington, KY), Gregory T. Webb (Lexington, KY), Trevor D. Gray (Versailles, KY), Jason T. McReynolds (Lexington, KY)
Application Number: 13/928,514
International Classification: G01C 9/20 (20060101);