1. Field of the Invention
The present invention relates to a dosing device and, in particular, to a dosing device for demand-dosing a liquid and to a writing apparatus having such a dosing device.
2. Description of the Related Art
An electronically controlled writing apparatus is disclosed in EP 0096177. The electronic writing apparatus includes a writing tip extending into a capillary space also referred to as the secondary supply space. The small-volume secondary supply space is fluidically connected to a large-volume primary ink supply space under pressure via an ink channel, a reload valve being arranged in the ink channel. When the fluid level in the secondary supply space is too low, the reload valve is controlled in order to open for a certain time until a sufficient amount of ink has been transported from the primary supply space into the secondary supply space so that a sufficient filling level appears there. The filling level height in the secondary supply space is measured using a capacitive sensor. The capacitive sensor is embodied as a cylinder capacitor, the capacity of which depends on the filling volume of the secondary supply space. In order to be able to measure small capacity changes, a resonance circuit digitally measuring the capacity change by detuning an oscillating circuit is used. This circuit, apart from the capacity to be measured, includes an additional capacity and a quartz oscillator. Additionally, a counting mechanism is used to be able to measure the difference of the oscillating frequencies as an indication to the capacity change.
Devices for demand-dosing form a regulating system including a supply tank, a buffer reservoir and a pressure-regulating unit. The release of the liquid is from the buffer reservoir. If the pressure in the buffer reservoir sinks below a certain threshold by releasing a liquid, the pressure in the buffer reservoir is compensated by the pressure-regulating unit by transferring liquid from the supply tank into the buffer reservoir.
Such dosing devices are vacuum-regulated or negative-pressure-regulated relative to the ambient pressure so that both the buffer reservoir and the supply tank must be closed in a pressure-tight way relative to the ambient pressure. In order to be, however, able to take a liquid from a pressure-tight vessel, a gas volume must be present in this vessel. This gas volume in turn is governed by the gas laws and, for example, expands when heated, which results in a pressure increase in the vessel. Thus the negative pressure in the vessel can be reduced so that the vacuum-regulated release of liquid no longer works. A further possible reduction of the negative pressure takes place by diminishing the ambient pressure.
In addition, such dosing devices require a unilateral connection of the supply tank and the buffer reservoir to the ambient air for the purpose of a gas inlet. This connection can, in case of a failure, result in a leakage of the liquid stored.
For certain dosing devices, as are, for example, to be used in a pen, the demand-release of a liquid is important. The amount released should be able to adapt directly to the requirements of the consumer, that is in the case of a pen to its writing speed. It must be guaranteed that the liquid stream is not interrupted in a constant or changing consumption. Such a case of failure of the interruption could, for example, occur when releasing from a closed tank since when emptying it changing pressure ratios can be present and thus the liquid stream can pulse.
A further case of failure can occur by evaporating the liquid at the point of release. Solid residues from the liquid, which in the case of a pen is the ink, could plug the release opening and not allow any further release. Thus, it must be guaranteed that either no evaporation occurs or the point of release is always wetted with a liquid. The latter case of the continuous wetting requires a liquid to flow in a regulated way according to the evaporating rate.
DE 33 21 301 A1 discloses an ink supply system for writing apparatuses operating with a liquid ink, having a large volume ink space connected to a small volume ink supply space next to the writing element via a reload valve. Transferring ink from the large volume ink space to the secondary supply space takes place in a way controlled by a sensor depending on the ink volume present in the secondary ink space. As a reload valve, a hose pump which is driven in a rotating way by an electric motor and which can produce the delivery pressure required for delivering the ink to the secondary ink space is used.
It is the object of the present invention to provide a safe dosing device for demand-dosing a liquid.
In accordance with a first aspect of the invention, this object is achieved by a dosing device for demand-dosing a liquid, comprising:
a primary container for storing the liquid; a point of release for releasing the liquid; a main liquid channel between the primary container and the point of release; a secondary container for buffering the liquid, the secondary container comprising a vent, the secondary container being connected to a branch point in the main liquid channel, and the secondary container being coupled to the main liquid channel such that the main liquid channel preferably fills with the liquid before the secondary container; a valve between the primary container and the branch point; a sensor for measuring the filling level in the secondary container; and means for opening the valve responsive to a predetermined filling level in the secondary container.
It is a further object of the present invention to provide a writing apparatus for a liquid writing medium having such a dosing device.
In accordance with a second aspect of the invention, this object is achieved by a writing apparatus for a liquid writing medium, comprising:
a dosing device having a primary container for storing the liquid; a point of release for releasing the liquid; a main liquid channel between the primary container and the point of release; a secondary container for buffering the liquid, the secondary container comprising a vent, the secondary container being connected to a branch point in the main liquid channel, and the secondary container being coupled to the main liquid channel such that the main liquid channel preferably fills with the liquid before the secondary container; a valve between the primary container and the branch point; a sensor for measuring the filling level in the secondary container; and means for opening the valve responsive to a predetermined filling level in the secondary container; writing means coupled to the point of release.
The present invention is based on the finding that the concept wherein the liquid released directly reaches the point of release from the buffer volume has to be dismissed. Instead, in the inventive dosing device, the liquid released is fed via the main liquid channel extending directly from the primary container to the point of release. For detecting the liquid stream from the primary container via the main liquid channel to the point of release of the dosing device, a secondary container is fluidically coupled to the main fluid channel at a branch site, i.e. arranged in an auxiliary stream. The liquid level in the secondary container is measured by means of a filling level sensor which in turn feeds a valve control to control a valve in the main liquid channel provided between the primary container and the branch site. According to the invention, the secondary container is vented and coupled to the main fluid channel such that the main fluid channel preferably fills with the liquid before the secondary container.
The inventive dosing device thus uses the filling level in the auxiliary stream as a regulating quantity, while in the prior art the filling level in the main stream has been used for controlling the valve. Since the valve in the inventive dosing device actively prevents the undesired re-flow of a liquid from the primary container, apart from venting the secondary container, venting the primary container can also be provided. The gas pressures in the primary container and in the secondary container can thus always be at ambient pressure.
The flow in the main liquid channel is, according to the invention, not measured directly in the main stream itself, but via the filling level in the secondary container separated from the main stream, which is coupled to the main stream such that the main stream preferably fills before the auxiliary stream. This can be obtained in preferred embodiments of the present invention by a capillary-dimensioning of the main liquid channel and the secondary container. If liquid is released, the filling level in the secondary container sinks and vice versa. The consumption of liquid can be measured directly via this change and the re-flow can be regulated via the valve depending thereon.
An advantage of the present invention is that both the secondary container and the primary container can be embodied independently of the ambient pressure and the ambient temperature. The cases of failure caused thereby thus can no longer occur.
A further advantage of the present invention is that by a suitable selection of the surface characteristics within the secondary container and the adjacent channels, there is the possibility to configure the capillary forces such that the dosing device, when it is not to release a liquid, does not run out autonomously or the secondary volume does not run over when the pressure in the main liquid channel is increased.
A further advantage of the present invention is that the secondary container can be vented and be dimensioned by geometrically designing such that the capillary pressure in the secondary container decreases with an increasing in filling level. This can be realized in preferred embodiments of the present invention by enlarging the cross-section along the filling path. For such a disproportionate increase in the volume along the filling path in the secondary container, a clear filling or release direction can be designed in the secondary container, in particular in capillary systems.
Preferred embodiments of the present invention will be detailed subsequently referring to the appended drawings, in which:
a shows a coupling of the secondary container to the main liquid channel according to an embodiment of the invention;
b shows a coupling of the secondary container to the main liquid channel according to a further embodiment of the present invention;
c shows a coupling of the secondary container to the main liquid channel according to a further embodiment of the present invention;
a to 3c show principle sketches for discussing the function of a conventional hydrostatic pen.
Before an inventive electronic writing apparatus, such as, for example, an electronic pen in which the dosing principle according to the present invention can be used with a special advantage will be detailed subsequently, reference will be made at first to
A conventional pen can generally be considered to be a complex microdosing system. A feature of this system is that all the essential fluidic functions are integrated in the single cheap-manufacturability plastic component 74.
The fluidic system shows weaknesses when so-called cases of failure arise, such as, for example, the change of the ambient temperature and the change of the exterior air pressure, as can, for example, occur within a starting airplane.
In the following, reference is made to
During ventilation, ink flows from the cartridge 72. In order to avoid an uncontrolled release to the paper in this phase, the part of the ink volume not used for writing must be stored in the compensation chambers 84 forming a buffer or a secondary volume. Typically, the buffer is formed as a capillary storage below the quill 76 in the form of plane-parallel plates referred to as compensating chambers. This storage takes up the excess amount of ink and releases it again to the paper in the course of the continued writing process. If the buffer is empty, the ink required for writing is taken from the cartridge 72. The negative pressure thus increases in it and when the value decreases below the critical value, the short capillary value 80 opens again and the cycle starts anew.
When the ambient temperature changes, the air volume present in the cartridge 72 expands and displaces ink stored. The process also takes place when the exterior air pressure changes. The ink volume escaping from the cartridge 72 in such cases of failure must be taken up by the compensating chambers 84 under the quill. The usage of the system is thus strongly limited by the space available in the secondary volume under the quill.
A disadvantage of this conventional system is the limited tolerance for the case of a failure. A further disadvantage is that the reliable function of the system is strongly dependent on the tuning of the capillary pressures acting in the vent 80 and the secondary volume 84. They in turn are a function of the surface features of the materials used and thus strongly dependent on the manufacturing parameters and contaminations of the surfaces.
This valve, in the state of rest, is closed and avoids the release of ink from the primary container 10 to the writing quill 24 when temperature and pressure change. In operation, the valve 18 is controlled by the sensor 30 and the valve control 32. As will be discussed subsequently referring to
When writing, ink is released via the point of release 22 and the writing quill 24 from the main liquid channel. The ink is from the secondary container, when it is assumed that the valve is presently closed. The ink is, however, not released directly from the secondary container but from the main liquid channel since the secondary container communicates with the point of release only via the main liquid channel and not directly. If the ink volume in the secondary container is emptied under a defined point, the valve 18 will be opened again and ink flows to the buffer volume in the secondary container. If the filling level in the secondary container has again reached an upper limit, the valve will be closed again. The valve control can take place by means of a two-step regulator which monitors the minimum or the maximum filling level of the secondary container. In addition, an analog regulation which opens the valve corresponding to the filling level in the secondary container to a larger or a lesser degree is, however, also possible. In the inventive dosing device, the primary container can be vented or be under pressure. According to the invention, considering the high stress of the valve 18 when the primary container is under pressure, a vented primary container is preferred. It is to be pointed out that with a primary supply container under pressure a relatively strong valve is required in order to endure the pressure of the supply container. This may lead to increased costs of the overall system.
a shows an enlarged view of a writing tip 40 having a writing quill 24 comprising a grain 42 at its front tip. Below the writing quill 24, there is the main liquid channel 16 ending below the writing tip at the point of release 22. Within the writing tip, there is additionally the branch point 20 also referred to as the fluidic T-piece. In the auxiliary stream, there is the secondary container formed in the embodiment shown in
In order to guarantee the preferred filling of the main fluid channel 16, a capillary negative pressure is produced, which is larger in the main stream than in the secondary container 26. This is realized by a capillary gap in the secondary container 26 larger than in the main stream. These facts are schematically illustrated in
b shows an alternative design of a writing tip 40″ in which the secondary container 26 is directly below the writing quill 24. This design has the advantage that the bore usually present in the writing quill can be used as a vent 28 of the secondary container 26. The preferred filling of the main fluid channel 16 in turn is guaranteed by a capillary negative pressure by embodying the capillary gap of the main stream to be larger than the capillary gap in the auxiliary stream, that is the capillary gap formed by the auxiliary liquid channel 26a and the storage region 26b.
c shows another possibility of the design of the writing tip 40″, wherein the secondary container in the embodiment shown in
For all the embodiments shown in
Different sensors can be employed as filling level sensors, such as, for example, a conductivity sensor, a resonance sensor, an optical sensor or a capacitive sensor. For the application of the inventive dosing device in an electronic pen, a capacitive filling level sensor comprising an electrode arrangement, a passivation layer arranged on the electrode arrangement and a contact electrode is preferred. In this preferred capacitive filling level sensor, the contact electrode is in an electrically conductive contact to the electrically conductive ink so that the electrically conductive ink acts as a capacitor electrode, the electrode arrangement acts as another capacitor electrode and the area of the passivation layer wetted by the electrically conductive liquid acts as a dielectric of a measurement capacitor, the capacity of which depends on the degree of wetting of the passivation layer by the electrically conductive liquid. Such a sensor excels, due to the usage of the liquid to be measured as an electric conductor and thus as a capacitor plate, by a high sensitivity and by a very low dependence on the liquid to be measured.
Suitable materials for designing the main fluid channel and the secondary container are polypropylene (PP), polycarbonate (PC) or LCP. These materials, in themselves, are non-wetting but can be activated and etched well in order to have wetting surface features. In particular, ABS is to be mentioned for the wetting materials.
While this invention has been described in terms of several preferred embodiments, there are alterations, permutations, and equivalents which fall within the scope of this invention. It should also be noted that there are many alternative ways of implementing the methods and compositions of the present invention. It is therefore intended that the following appended claims be interpreted as including all such alterations, permutations, and equivalents as fall within the true spirit and scope of the present invention.
Number | Date | Country | Kind |
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100 54 599 | Nov 2000 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP01/12647 | 10/31/2001 | WO | 00 | 11/24/2003 |
Publishing Document | Publishing Date | Country | Kind |
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WO02/36361 | 5/10/2002 | WO | A |
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4573819 | Herrnring | Mar 1986 | A |
4634305 | Herrnring | Jan 1987 | A |
5443322 | Jozat et al. | Aug 1995 | A |
Number | Date | Country |
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3211586 | Mar 1982 | DE |
3220750 | Jun 1982 | DE |
3311364 | Mar 1983 | DE |
3321301 | Jun 1983 | DE |
3926271 | Aug 1989 | DE |
4416880 | May 1994 | DE |
4443212 | Dec 1994 | DE |
096177 | Mar 1983 | EP |
Number | Date | Country | |
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20040090492 A1 | May 2004 | US |