The invention relates generally to the control of a trajectory of a fluid moving in free space. More particularly, the invention relates to apparatus and methods of trajectory correction of liquid droplets moving through free space via directed fluid flows and electrostatic devices.
Various technologies have been developed utilizing techniques in which fluids are ejected from a reservoir by focused acoustic energy. An example of such technology is typically referred to as acoustic ink deposition which uses focused acoustic energy to eject droplets of a fluid, such as ink, from the free surface of that fluid onto a receiving medium.
Generally, when an acoustic beam impinges on a free surface, e.g., liquid/air interface, of a pool of liquid from beneath, the radiation pressure will cause disturbances on the surface of the liquid. When the radiation pressure reaches a sufficiently high level that overcomes the surface tension of the liquid, individual droplets of liquid may be ejected from the surface.
However, many different factors may arise which can interfere with the droplet ejection and resulting droplet trajectory. For instance, care must be taken to accurately direct the acoustic beam to impinge as exclusively as possible on the desired lens which focuses the acoustic beam energy. Some undesirable effects of the acoustic beam impinging other than on the desired lens include insufficient radiation pressure on the liquid surface, lens cross-talk, and generation of undesirable liquid surface disturbances. Each of these effects may result in the loss or degradation of droplet ejection control.
A further problem related to liquid surface disturbances include surface waves affecting the surface planarity. These waves result in deviations of the free surface from planar and alter the location of the surface relative to the focal point of the lens, thereby resulting in degradation of droplet ejection control. The result of this is a varying angle of droplet ejection.
Droplets will tend to eject in a direction normal to the liquid surface. For optimum control of placement of the droplet onto an opposing target medium, conventional methods have included maintaining ejection angles of the droplets at a predetermined value, generally perpendicular to the local angle of the surface of the opposing target medium. Accordingly, attempts have been made to maintain a liquid surface parallel to the target medium. Surface disturbances will vary the local surface angle of the liquid pool, especially over the acoustic lenses. This typically results in drop ejection at varying ejection angles with a consequent loss of deposition alignment accuracy and efficiency.
Other conventional methods have included increasing the energy required to cause the droplet ejection to account for varying droplet ejection angles; however, this may have adverse effects on droplet size, droplet count, and droplet ejection direction control.
Another conventional method includes varying the transducer size such that illumination outside the lens is minimized. A further method has included increasing the radius of the acoustic lens itself such that the diverging acoustic waves impinge fully on the lens. However, this generally increases the size and cost of the system and is not necessarily efficient in controlling the droplet ejection angles.
Small volumetric liquid droplets moving individually through free space over distances greater than about 100 times their diameter typically have problems repeating the same trajectory and positional orientation. Accordingly, there remains a need for an efficient device and method for effectively controlling, steering, or correcting the trajectories of droplets ejected from a liquid surface such that they are accurately placed on a targeting medium.
An apparatus and method for steering droplets, i.e., correcting or altering the trajectory of droplets moving through free space, by utilizing directed fluid flow is disclosed herein. Generally, a throated structure preferably comprising a nozzle defining a throat may have an inlet or entrance port and a preferably smaller outlet or exit port. A venturi structure may also be used in which case the inlet or entrance port may open into a nozzle which converges to a narrower throat and reopens or diverges into a larger outlet or exit port. Use of a venturi structure, however, may result in longer flight times for the ejected droplets prior to reaching the targeting medium.
In the case of a nozzle defining a throat having an inlet or entrance port and a smaller outlet or exit port, the throat preferably converges from a larger diameter inlet to a smaller diameter outlet. Through this throat, a vectored or directed fluid stream may be directed into the inlet to be drawn through the structure. The fluid stream is preferably driven through the system via a pump, either a positive or negative displacement pump, such as a vacuum pump. As the fluid stream approaches the outlet, the fluid may increase in velocity and is preferably drawn away from the centerline of the nozzle through a connecting deviated fluid flow channel. The fluid stream may be drawn away from the throat at a right angle from the centerline of the nozzle or at an acute angle relative to the nozzle centerline. The fluid stream may then continue to be drawn away from the throat and either vented or recycled through or near the inlet again. The fluid used, e.g., air, nitrogen, etc., may comprise any number of preferably inert gases, i.e., gases which will not react with the droplet or with the liquid from which the droplet is ejected. However, a fluid that is highly reactive with the ejected liquid droplet may also be used. This reactive fluid may be comprised of several compounds or a single fluid.
A droplet ejected from the surface of a liquid will typically have a first trajectory or path. The liquid is preferably contained in a well or reservoir disposed below the nozzle. If the trajectory angle of the droplet relative to a centerline of the inlet nozzle is relatively small, i.e., less than a few tenths of a degree off normal, the droplet may pass through the outlet and on towards a target with an acceptable degree of accuracy. If the trajectory angle of the droplet is relatively large, i.e., greater than a few degrees and up to about ±22.5°, the droplet may be considered as being off target.
As the droplet enters the inlet off-angle and as it advances further up into the structure, the droplet is introduced to the high velocity fluid stream at the perimeter of the interior walls of the nozzle. The fluid stream accordingly steers or redirects the momentum of the droplet such that it obtains a second or corrected trajectory which is closer to about 0° off-axis. The fluid stream at the connecting deviated fluid flow channel is preferably drawn away from the centerline of the nozzle and although the droplet may be subjected to the fluid flow from the connecting deviated fluid flow channel, the droplet has mass and velocity properties that constrain its ability to turn at right or acute angles when traveling at a velocity, thus the droplet is allowed to emerge cleanly from the outlet with high positional accuracy. Throated structure may correct for droplet angles of up to about ±22.5°, but more accurate trajectory or correction results may be obtained when the droplet angles are between about 0°–15° off-axis.
To facilitate efficient fluid flow through the throated structure, the throat is preferably surrounded by a wall having a cross-sectional elliptical shape. That is, the cross-sectional profile of the wall taken in a plane that is parallel to or includes the axis of the nozzle preferably follows a partial elliptical shape. The exit channels which draw the fluid away from the centerline of the throat may also have elliptically shaped paths to help maintain smooth laminar flow throughout the structure. It also helps to bring the fluid flow parallel to the centerline as well as maintaining a smooth transition for the exit flow as well as maintaining an equal exit flow on the throat diameter. This in turn may help to efficiently and effectively eject droplets through the structure.
In addition to the throated structure, alternative variations of the device may include a variety of additional methods and/or components to aid in the fluid flow or droplet steering. For instance, the nozzle may be mounted or attached to a platform which is translatable in a plane independent from the wellplate over which the nozzle is located. As the wellplate translates from well to well and settles into position, the nozzle may be independently translated such that as the wellplate settles into position, the nozzle tracks the position of a well from which droplets are to be ejected and aligns itself accordingly. The nozzle may be tracked against the wellplate and aligned by use of a tracking system such as an optical system, e.g., a video camera, which may track the wells by a tracking algorithm on a computer.
Additionally, an electrically chargeable member, e.g., a pin, may be positioned in apposition to the outlet to polarize the droplets during their travel towards the target. Polarizing the droplets helps to influence the droplet trajectory as the droplets are drawn towards the chargeable member for more accurate droplet deposition. Additionally, well inserts for controlling the ejection surface of the pool of source fluid from which the droplets are ejected may also be used in conjunction with the throated structure. Furthermore, various manifold devices may be used to efficiently channel the fluid through the system.
Aside from manifold devices, a variation using a separately attachable lid assembly may also be used. The lid assembly may be placed over a conventional wellplate and may define any number of nozzles or throats within the plate, the number of nozzles preferably corresponding to the number of wells within the wellplate. Rather than utilizing a single nozzle or throat for the entire wellplate, each well may have its own dedicated nozzle which may be individually placed in fluid communication with a fluid source assembly positioned over the lid assembly. The fluid stream may be drawn into the assembly through a number of fluid stream inlets coming into fluid communication through a common plenum with each of the nozzles.
A capillary well mask may also be used with the lid assembly. Such a well mask would preferably have a number of capillary tubes formed on the mask and each tube would be capable of being inserted individually within a number of corresponding wells within the wellplate. After the capillary tubes are placed within the corresponding wells, the liquid contained within the wells may tend to be pulled into their respective tubes and drawn up through the tube orifice by capillary action. The liquid may then rise to a level within a tube which is constant relative to the liquid levels in other tubes. Because each well could have its own individual capillary tube, the focal point across each of the wells may be constant such that a droplet generator would not need to focus and refocus its energy for ejecting droplets for different wells having different liquid levels without such a capillary tube.
Another variation may include using a well mask having a variable orifice diameter defined therein for use either with a single throated structure design, or using a well mask with multiple orifices for use with a lid assembly having multiple throats defined therein and placed over a wellplate. Such a well mask may be used particularly with wellplates having relatively large diameter wells, i.e., wells with diameters measuring 4.5 mm or greater, to emulate a smaller diameter well to aid in fluid flow efficiency.
An apparatus and method for droplet steering, i.e., correcting or altering the trajectory of a droplet moving through free space, by utilizing directed fluid flow, e.g., gas flow, is disclosed herein. A representative schematic diagram of a non-contact fluid transfer system 2 is shown in
As droplet 26 is ejected from the surface of liquid, it will have a first trajectory or path 28. The volume of the droplets are preferably less than or equal to about 15,000 picoliters (10−12 liters) and droplet 26 diameters preferably range from about 5–300 microns. Also, droplet 26 densities preferably range from about 0.5–2.0 grams/milliliter. If the trajectory angle of droplet 26 relative to a centerline 17 of nozzle 12 is relatively small, i.e., less than a few degrees off normal, droplet 26 may pass through outlet 18 and on towards target 8 with some degree of accuracy. If the trajectory angle of droplet 26 is relatively large, i.e., up to about ±22.5°, droplet 26 may be considered as being off target. However, with fluid stream 20 flowing through structure 10, a droplet 26 may be ejected from a well located below structure 10. As droplet 26 enters inlet 16 off target and as it advances further up into structure 10, droplet 26 is introduced to the high velocity fluid stream 20 at the perimeter of the interior walls of nozzle 12, as seen at the point of capture 30. Fluid stream 20 accordingly steers or redirects the momentum of droplet 26 such that it obtains a second or corrected trajectory 32 which is closer to about 0° off-axis. The fluid stream 20 at deviated channel 22 is drawn away from the centerline 17 of nozzle 12 and although droplet 26 may be subjected to the deviated vector of fluid flow 20, droplet 26 has mass and velocity properties that constrain its ability to turn at right or acute angles while traveling at some velocity, thus droplet 26 is allowed to emerge cleanly from outlet 18 with high positional accuracy. Throated structure 10 may correct for droplet 26 angles of up to about ±22.5°, but more accurate trajectory or correction results may be obtained when droplet 26 angles are between about 0°–15° off-axis for the given velocity, droplet size, and mass present in the current system. For example, a given droplet 26 of water having a velocity of about 1–10 m/s, a diameter of about 10–300 microns with a volume of about 0.5–14,000 picoliters, and a mass of about 500 picograms (500×10−12 grams) to 14 micrograms (14×10−6 grams) may have its trajectory correctable within the angles of ±22.5°, but the angles of correction are subject to variations depending upon the mass and velocity properties of the droplet 26.
With the general operation of the droplet steering apparatus described,
On the surface of main body 40 which is opposite to nozzle 12, fluid flow channel 22 is preferably located to allow for the drawing away of the fluid from the centerline 17 of nozzle 12. The fluid that exits outlet 18 and is drawn away via channel 22 may then be routed away from main body 40 through routing outlets 48, which may direct the fluid back through main body 40 and out through fluid outlet 50. This variation shows three routing outlets 48 exiting through their corresponding fluid outlets 50 to evenly distribute the fluid flow, but any number of outlets 48 and 50 that is practicable may be used. To facilitate the fluid stream entering fluid inlets 46, channels 44 may be defined in the surface of main body 40 adjacent to nozzle 12. Channels 44 are preferably passages notched into main body 40 and extend radially from nozzle 12 to give the fluid stream sufficient space to flow above a wellplate when main body 40 is in use. Preferably, the space is also sufficiently large such that the flowing fluid does not disturb the surface of the liquid. Main body 40 may be made from a variety of materials, for instance, moldable thermoset plastics, preferably provided that the plastic is resistant to building up an electrostatic charge, die-cast metals, etc.
Furthermore, structure 60 may have a variety of shaped walls, for instance, it may have simple conically-shaped walls converging from inlet 16 to outlet 18, or it may have non-elliptical curved or arcuate shaped walls. Flow velocities through throated structure 60 may be simply calculated based upon the diameters of inlet 16 and outlet 18. For example, assuming an inlet 16 diameter of 3 mm and an outlet 18 diameter of 1 mm, a fluid having an initial velocity of 1 m/s at inlet 16 will have a velocity of 9 m/s at outlet 18. Aside from flow velocity, flow rate of the fluid through throated structure 60 preferably ranges from about 0.5–5 standard liters per minute with the distance from the wellplate to the proximal end of throated structure 60 about 0.25–8 mm.
An example of droplet steering assembly 70 is shown in use in
In operation, droplet 26 is ejected from source fluid 76 by various methods, such as acoustic energy. Once ejected, droplet 26 enters main body 40 through inlet 16 along a first trajectory or path 28. The flow of fluid, as shown by flow lines 20, may be seen in this variation entering main body 40 also through inlet 16, although the fluid may enter through separate fluid inlets defined near the proximal end of nozzle 12 in other variations. As the fluid is directed through main body 40, as shown by flow lines 20, it may inundate droplet 26 and transfer momentum to droplet 26 to alter its flight path to a second or corrected trajectory 32 such that droplet 26 passes through outlet 18 with the desired trajectory towards target 78. Meanwhile, the fluid is preferably diverted away from the centerline 17 of the throat near outlet 18 along fluid flow channel 22, through routing outlet 48, and out through fluid outlet 50. If droplet 26 enters main body 40 with a desirable first trajectory 28, i.e., a trajectory traveling close to or coincident with the centerline 17 of the throated structure, droplet 26 may experience little influence from flow lines 20 and accordingly little correction or steering, if any, may be imparted to droplet 26. The fluid may be pushed through assembly 70 through positive pressure via a pump (pump is not shown) in fluid communication with main body 40 or preferably the fluid may be drawn through the system through negative pressure via a vacuum pump (vacuum pump is not shown) in fluid communication with main body 40 through fluid outlet 50.
The main body 40 may be further mounted or attached to a platform which is translatable in a plane independently from wellplate 72 for use as a fine adjustment mechanism as droplets 26 are ejected from the various source fluids 76 in each of the different wells 74. The translation preferably occurs in the plane which is parallel to the plane of wellplate 72, as shown by the direction of arrows 52 which denote the direction of possible movement. Although arrows 52 denote possible translation to the left and right of
In operation, wellplate 72 may be translated using, e.g., conventional linear motors and positioning systems, to selectively position individual wells 74 beneath main body 40 and inlet 16. As wellplate 72 is translated from well to well, time is required not only for the translation to occur, but time is also required for the wellplate 72 to settle into position so that well 74 is aligned properly beneath inlet 16. To reduce the translation and settling time, main body 40 may also be independently translated such that as wellplate 72 settles into position, main body 40 tracks the position of a well 74 and aligns itself accordingly. Main body 40 may be aligned by use of a tracking system such as an optical system, e.g., video camera 56, which may be mounted in relation to main body 40 and individual wells 74. Video camera 56 may be electrically connected to a computer (not shown) which may control the movement of the platform holding main body 40 or main body 40 itself to follow the movement of wellplate 72 as it settles into position. Aside from the translation, main body 40 may also rotate independently during the settling time of wellplate 72 to angle inlet 16 such that it faces the preselected well 74 at an optimal position. The fine adjustment processes, i.e., translation either alone or with the rotation of main body 40, may aid in reducing the time for ejecting droplets from multiple wells and may also aid in improving accuracy of droplets deposited onto target medium 78.
A system such as droplet steering assembly 70 is proficient in altering or correcting a droplet trajectory. It may also be useful for polar liquids such as aqueous solutions or suspensions. To further facilitate the droplet trajectory correction, another variation of droplet steering assembly 80 is shown in
F=x·p·∇E (1)
where,
To further aid in generating an accurate trajectory of a droplet ejected from a pool of source fluid,
As further seen in
In addition to capillary tube 92, further modifications may be made to facilitate the droplet steering. A further variation on droplet steering assembly 110 is seen in the exploded isometric view of
An alternative manifold design is shown in the exploded top and bottom isometric views of droplet steering assembly 130 of
A further variation on the droplet steering assembly is shown in
The fluid source assembly 150 is preferably affixed at one end 158 and is located above droplet array 144. Fluid source assembly 150 may comprise manifold 154, shown as an elongate apparatus but which may be made of any amenable shape. Within manifold 154 is channel 155 which preferably extends throughout manifold 154 and may be sealed by top plate 152. At the opposite end of assembly 150, receiving channel 160 may be defined within manifold 154 for drawing the fluid therethrough which may be used to steer the droplet and droplet orifice 156 may be defined in top plate 152 and aligned with channel 160 for allowing the droplet to pass through towards the targeting medium. Channel 155 is defined such that it is preferably perpendicularly positioned relative to a centerline defined by droplet orifice 156. Fluid flow lines 162 are shown in
System 140 may also have an optional well mask 164 disposed within lid assembly 142, as seen in the exploded view of
As fluid flow 200 is drawn through flow channel 196 and throat 184, a droplet may be ejected from droplet reservoir 198, as shown. As it is ejected, the droplet may then pass through orifice 166 defined within well mask 164 and then passes through throat 184 and exits through droplet orifice 156 in much the same manner as again described above.
A further optional variation of lid assembly 142 may include a variation on the well mask contained therewithin. As seen in
Yet another variation is seen in
A further variation of the well mask which may be used with large diameter wells is shown in
The applications of the droplet steering assemblies discussed above are not limited to acoustically ejected droplets but may include any number of further droplet or discrete fluid volume applications. Modification of the above-described assemblies and methods for carrying out the invention, and variations of aspects of the invention that are obvious to those of skill in the art are intended to be within the scope of the claims.
This application claims the benefit of priority of U.S. Provisional Patent Application 60/348,429 entitled “Apparatus and Method for Droplet Steering” filed Oct. 29, 2001, which is incorporated herein by reference in its entirety.
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